Transmission method

ABSTRACT

Provided is a transmission method that contributes to an increase in data reception quality when iterative detection is performed at a receive apparatus side. A transmit apparatus alternates between two types of modulation scheme that each shift amplitude and phase, performs mapping to constellation points according to a selected modulation scheme, and transmits a modulated signal obtained by mapping.

TECHNICAL FIELD

(Related applications) All content disclosed in the claims, descriptions, drawings, and abstracts of Japanese Patent Application 2013-084269, Japanese Patent Application 2013-084270, and Japanese Patent Application 2013-084271, filed Apr. 12, 2013; and Japanese Patent Application 2013-099605, Japanese Patent Application 2013-099606, and Japanese Patent Application 2013-099607, filed May 9, 2015, is incorporated into the present application.

The present invention is related to transmission methods of signals for performing iterative detection at a receive apparatus side.

BACKGROUND ART

Conventionally, as in Non-Patent Literature 1, with respect to quadrature amplitude modulation (QAM), studies have been carried out into improvements in reception quality of data for bit interleaved coded modulation with iterative detection (BICM-ID) by changing aspects of bit labelling.

CITATION LIST Patent Literature

Patent Literature 1

Japanese Patent Application Publication 2013-16953

Non-Patent Literature

Non-Patent Literature 1

A. Chindapol and J. A. Ritcey, “Design, analysis, and performance evaluation for BICM-ID with square QAM constellations in Rayleigh fading channels” IEEE Journal on selected areas in communication, vol. 19, no. 5, pp. 944-957, May 2001

Non-Patent Literature 2

Transmission System for Advanced Wide Band Digital Satellite Broadcasting, ARIB Standard STD-B44, Ver. 1.0, July 2009

SUMMARY OF INVENTION Technical Problem

Modulation schemes other than QAM, such as amplitude phase shift keying (APSK), may be used due to peak-to-average power ratio (PAPR) limitations, etc., and therefore application to communication/broadcast systems of the techniques of Non-Patent Literature 1 that relate to QAM labelling may be difficult.

The present invention has an aim of providing a transmission method that contributes to improvement in data reception quality when iterative detection is performed on a receive apparatus side in, for example, a communication/broadcast system.

Solution to Problem

A transmission method pertaining to the present invention is applicable to a transmit apparatus for transmitting data by modulation schemes that shift amplitude and phase, the transmit apparatus comprising: a selector that alternately selects a first modulation scheme and a second modulation scheme for each symbol, a constellation and bit labelling of each constellation point of the first modulation scheme being different to a constellation and bit labelling of each constellation point of the second modulation scheme; a mapper that performs mapping by using constellation points of a selected modulation scheme; and a transmitter that transmits a modulated signal obtained by the mapping, wherein the first modulation scheme is 16 amplitude phase shift keying (APSK) modulation that arranges, in a first in-phase (I)-quadrature-phase (Q) plane, 16 constellation points composed of four constellation points on the circumference of a first inner circle and twelve constellation points on the circumference of a first outer circle, the first inner circle and the first outer circle being concentric circles, wherein: when the 16 constellation points are divided into four groups each composed of one constellation point on the circumference of the first inner circle and three constellation points on a portion of the circumference of the first outer circle in a direction from the origin of the first I-Q plane to the one constellation point, only one bit is different in bit labelling between each pair, within each group, of constellation points adjacent on the circumference of the first outer circle, and only one bit is different in bit labelling between each pair, within each group, of each constellation point on the circumference of the first inner circle and each constellation point at one of two ends of each portion of the circumference of the first outer circle; and only one bit is different in bit labelling between each pair, between different groups, of constellation points that are closest to each other on the first I-Q plane on the circumference of the first outer circle, and only one bit is different in bit labelling between each pair, between different groups, of constellation points that are closest to each other on the first I-Q plane on the circumference of the first inner circle, and the second modulation scheme is 16APSK modulation that arranges, in a second I-Q plane, 16 constellation points composed of eight constellation points on the circumference of a second inner circle and eight constellation points on the circumference of a second outer circle, the second inner circle and the second outer circle being concentric circles, wherein: when the 16 constellation points are divided into a first group composed of the eight constellation points on the circumference of the second inner circle and a second group composed of the eight constellation points on the circumference of the second outer circle, only one bit is different in bit labelling between each pair, within the first group, of constellation points that are adjacent on the circumference of the second inner circle, and only one bit is different in bit labelling between each pair, within the second group, of constellation points that are adjacent on the circumference of the second outer circle.

Advantageous Effects of Invention

The transmission method pertaining to the present invention, in particular when applied to a communication/broadcast system using error correction code having a high error correction capacity, such as low density parity check (LDPC) code and turbo code such as duo-binary turbo code, can contribute to improving data reception quality at a receive apparatus side at the time of initial detection or when iterative detection is performed.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 illustrates an example of input/output power properties of a power amplifier mounted on a transmit apparatus.

FIG. 2 illustrates a configuration example of a communication system using a BICM-ID scheme.

FIG. 3 illustrates an example of input and output of a coder of a transmit apparatus.

FIG. 4 illustrates an example of a bit-reduction encoder of a transmit apparatus.

FIG. 5 illustrates an example of a bit-reduction decoder of a receive apparatus.

FIG. 6 illustrates an example of input and output of a XOR section of a bit-reduction decoder.

FIG. 7 illustrates a configuration of a transmit apparatus.

FIG. 8 illustrates a constellation of (12,4)16APSK.

FIG. 9 illustrates a constellation of (8,8)16APSK.

FIG. 10 illustrates a block diagram related to generation of a modulated signal.

FIG. 11 illustrates frame configuration of a modulated signal.

FIG. 12 illustrates an example of data symbols.

FIG. 13 illustrates an example of pilot symbols.

FIG. 14 illustrates an example of labelling of (12,4)16APSK.

FIG. 15 illustrates an example of labelling of (12,4)16APSK.

FIG. 16 illustrates an example of labelling of (8,8)16APSK.

FIG. 17 illustrates an example of a constellation of (8,8)16APSK.

FIG. 18 illustrates a schematic of a transmit signal frame of advanced wide band digital satellite broadcasting.

FIG. 19 illustrates a configuration of a receive apparatus.

FIG. 20 illustrates examples of arrangement of modulation schemes.

FIG. 21 illustrates an example of arrangement of modulation schemes.

FIG. 22 illustrates an example configuration of stream type/relative stream information.

FIG. 23 illustrates examples of arrangement of modulation schemes.

FIG. 24 illustrates an example of arrangement of symbols.

FIG. 25 illustrates examples of constellations of 32APSK.

FIG. 26 illustrates an example of constellation and labelling of NU-16QAM.

FIG. 27 illustrates a schematic of wide band digital satellite broadcasting.

FIG. 28 illustrates a block diagram related to ring ratio determination.

FIG. 29 is a diagram for describing a bandlimiting filter.

FIG. 30 illustrates an example of a constellation of (4,8,4)16APSK.

FIG. 31 illustrates an example of a constellation of (4,8,4)16APSK.

FIG. 32 illustrates an example of a constellation of (4,8,4)16APSK.

FIG. 33 illustrates an example of arrangement of symbols.

FIG. 34 illustrates an example of arrangement of symbols.

FIG. 35 illustrates an example of arrangement of symbols.

FIG. 36 illustrates an example of arrangement of symbols.

FIG. 37 illustrates examples of arrangement of modulation schemes.

FIG. 38 illustrates an example of arrangement of modulation schemes.

FIG. 39 illustrates an example configuration of a transmit station.

FIG. 40 illustrates an example configuration of a receive apparatus.

FIG. 41 illustrates an example configuration of a transmit station.

FIG. 42 illustrates an example configuration of a transmit station.

FIG. 43 illustrates an example configuration of a transmit station.

FIG. 44 illustrates an example of frequency allocation of signals.

FIG. 45 illustrates an example configuration of a satellite.

FIG. 46 illustrates an example configuration of a satellite.

FIG. 47 illustrates an example configuration of extended information.

FIG. 48 illustrates an example of signaling.

FIG. 49 illustrates an example of signaling.

FIG. 50 illustrates an example of signaling.

FIG. 51 illustrates an example of signaling.

FIG. 52 illustrates an example of signaling.

FIG. 53 illustrates an example of signaling.

FIG. 54 illustrates an example of signaling.

FIG. 55 illustrates an example of signaling.

FIG. 56 illustrates an example of signaling.

FIG. 57 illustrates an example of signaling.

EMBODIMENTS

(Developments that LED to an Embodiment Pertaining to the Present) Invention

Typically, in a communication/broadcast system, in order to reduce power consumption of an amplifier for transmission and reduce errors in data at a receiver, a modulation scheme is preferred for which the peak-to-average power ratio (PAPR) is low and data reception quality is high.

In particular, in satellite broadcasting, in order to reduce power consumption of an amplifier for transmission, use of a modulation scheme for which PAPR is low is preferred, and (12,4) 16 amplitude phase shift keying (16APSK) is commonly used as a modulation scheme in which 16 constellation points exist in an in-phase (I)-quadrature-phase (Q) plane. Note that a constellation in an I-Q plane of (12,4) 16APSK modulation is described in detail later.

However, when (12,4) 16APSK is used in a communication/broadcast system, data reception quality of a receiver is sacrificed, and therefore there is a need to use, in satellite broadcasting, a modulation scheme/transmission method in which PAPR is low and data reception quality is high.

In order to improve reception quality, a modulation scheme having good bit error ratio (BER) properties may be considered. However, use of a modulation scheme having excellent BER properties is not necessarily the best solution in every case. This point is explained below.

For example, assume that when a modulation scheme #B is used, a signal-to-noise power ratio (SNR) of 10.0 dB is required to obtain a BER of 10⁵, and when a modulation scheme #A is used, an SNR of 9.5 dB is required to obtain a BER of 10⁻⁵.

When a transmit apparatus uses the modulation scheme #A or the modulation scheme #B at the same average transmission power, a receive apparatus can obtain a gain of 0.5 dB (10.0−9.5) by using the modulation scheme #B.

However, when the transmit apparatus is installed on a satellite, PAPR becomes an issue. Input/output power properties of a power amplifier installed on the transmit apparatus are illustrated in FIG. 1.

Here, when the modulation scheme #A is used, PAPR is assumed to be 7.0 dB, and when the modulation scheme #B is used, PAPR is assumed to be 8.0 dB.

The average transmit power when the modulation scheme #B is used is 1.0 (8.0−7.0) dB less than the average transmit power when the modulation scheme #A is used.

Accordingly, when the modulation scheme #B is used, 0.5−1.0=−0.5, and therefore the receive apparatus obtains a gain of 0.5 dB when the modulation scheme #A is used.

As described above, use of a modulation scheme that excels in terms of BER properties is not preferred in such a case. The present embodiment takes into consideration the points above.

Thus, the present embodiment provides a modulation scheme/transmission method for which PAPR is low and data reception quality is high.

Further, in Non-Patent Literature 1, consideration is given to how to label bits and how that improves data reception quality when bit interleaved coded modulation with iterative detection (BICM-ID) is used with respect to quadrature amplitude modulation (QAM). However, in some cases it is difficult to achieve the described effects using the approach used in Non-Patent Literature 1 (how to label bits with respect to QAM) for error correction code having high error correction capacity, such as low-density parity-check (LDPC) code and turbo code such as duo-binary turbo code.

In the present embodiment, a transmission method is provided for obtaining high data reception quality when error correction code having high error correction capacity is used, such as LDPC code and turbo code, and iterative detection (or detection) is performed at a receive apparatus side.

The following is a detailed description of embodiments of the present invention, with reference to the drawings.

(Embodiment 1)

The following describes in detail a transmission method, transmit apparatus, reception method, and receive apparatus of the present embodiment.

Prior to this description, an overview of a communication system using a BICM-ID scheme at a receive apparatus side is described below.

<BICM-ID>

FIG. 2 illustrates an example of a communication system using a BICM-ID scheme.

The following describes BICM-ID when a bit-reduction encoder 203 and a bit-reduction decoder 215 are used, but iterative detection may be implemented in cases without the bit-reduction encoder 203 and the bit-reduction decoder 215.

A transmit apparatus 200 includes a coder 201, an interleaver 202, the bit-reduction encoder 203, a mapper 204, a modulator 205, a radio frequency (RF) transmitter 206, and a transmit antenna 207.

A receive apparatus 210 includes a receive antenna 211, an RF receiver 212, a demodulator 213, a de-mapper 214, the bit-reduction decoder 215, a de-interleaver 216, a decoder 217, and an interleaver 218.

FIG. 3 illustrates an example of input/output bits of the coder 201 of the transmit apparatus 200.

The coder 201 performs coding at a coding rate R₁, and when N_(info) information bits are inputted, the coder 201 outputs N_(info)/R₁ coded bits.

FIG. 4 illustrates an example of the bit-reduction encoder 203 of the transmit apparatus 200.

The present example of the bit-reduction encoder 203, when a bit sequence b(b₀-b₇) of eight bits is inputted from the interleaver 202, performs a conversion that involves reducing the number of bits, and outputs a bit sequence m(m₀-m₃) of four bits to the mapper 204. In FIG. 4, “[+]” indicates an exclusive OR (XOR) section.

That is, the present example of the bit-reduction encoder 203 has: a branch that connects an input for bit b₀ to an output for bit m₀ via an XOR section; a branch that connects inputs for bits b₁ and b₂ to an output for bit m₁ via an XOR section; a branch that connects inputs for bits b₃ and b₄ to an output for bit m₂ via an XOR section; and a branch that connects inputs bits b₅, b₆ and b₇ to an output for bit m₃ via an XOR section.

FIG. 5 illustrates an example of the bit-reduction decoder 215 of the receive apparatus 210.

The present example of the bit-reduction decoder 215, when a log likelihood ratio (LLR) L(m₀)-L(m₃) for a bit sequence m(m₀-m₃) of four bits is inputted from the de-mapper 214, performs a conversion that involves restoring the original number of bits, and outputs an LLR L(b₀)-L(b₇) for a bit sequence b(b₀-b₇) of eight bits. The LLR L(b₀)-L(b₇) for the bit sequence b(b₀-b₇) of eight bits is inputted to the decoder 217 via the de-interleaver 216.

Further, the bit-reduction decoder 215, when an LLR L(b₀)-L(b₇) for a bit sequence b(b₀-b₇) of eights bits is inputted from the decoder 217 via the interleaver 218, performs a conversion that involves reducing the number of bits, and outputs an LLR L(m₀)-L(m₃) for a bit sequence m(m₀-m₃) of four bits to the de-mapper 214.

In FIG. 5, “[+]” indicates an XOR section. That is, the present example of the bit-reduction decoder 215 has: a branch that connects an input/output for L(b₀) to an input/output for L(m₀) via an XOR section; a branch that connects inputs/outputs for L(b₁) and L(b₂) to an input/output for L(m₁) via an XOR section; a branch that connects inputs/outputs for L(b₃) and L(b₄) to an input/output for L(m₂) via an XOR section; and a branch that connects inputs/outputs for L(b₅), L(b₆) and L(b₇) to an input/output for L(m₃) via an XOR section.

In the present example, with respect to a bit sequence b(b₀-b₇) of eight bits prior to bit reduction, bit b₀ is a least significant bit (LSB) and bit b₇ is a most significant bit (MSB). Further, with respect to a bit sequence m(m₀-m₃) of four bits after bit reduction, bit m₀ is an LSB and bit m₃ is an MSB.

FIG. 6 illustrates input/output of an XOR section, in order to describe operation of the bit-reduction decoder 215.

In FIG. 6, bits u₁ and u₂ are connected to bit u₃ via an XOR section. Further, LLRs L(u₁), L(u₂), and L(u₃) for bits u₁, u₂ and u₃ are illustrated. A relationship between L(u₁), L(u₂), and L(u₃) is described later.

The following describes processing flow with reference to FIG. 2 to FIG. 6. At the transmit apparatus 200 side, transmit bits are inputted to the coder 201, and (error correction) coding is performed. For example, as illustrated in FIG. 3, when a coding rate of error correction code used in the coder 201 is R₁, and N_(info) information bits are inputted to the coder 201, N_(info)/R₁ bits are outputted from the coder 201.

A signal (data) encoded by the coder 201 is, after interleaving processing by the interleaver 202 (permutation of data), inputted to the bit-reduction encoder 203. Subsequently, as described with reference to FIG. 3, bit number reduction processing is performed by the bit-reduction encoder 203. Note that bit number reduction processing need not be implemented.

A signal (data) on which bit reduction processing has been performed undergoes mapping processing at the mapper 204. The modulator 205 performs processing such as conversion of a digital signal to an analog signal, bandlimiting, and quadrature modulation (and multi-carrier modulation such as orthogonal frequency division multiplexing (OFDM) may also be implemented) on a signal on which mapping processing has been performed.

A signal that has undergone this signal processing is transmitted wirelessly from, for example, the transmit antenna 207, via transmit radio frequency (RF) processing (206) in which transmit processing is performed.

At the receive apparatus 210 side, the RF receiver 212 performs processing such as frequency conversion and quadrature demodulation on a signal (radio signal from a transmit apparatus side) received by the receive antenna 211, generates a baseband signal, and outputs to the demodulator 213.

The demodulator 213 performs processing such as channel estimation and demodulation, generates a signal after demodulation, and outputs to the de-mapper 214. The de-mapper 214 calculates an LLR for each bit, based on the receive signal inputted from the demodulator 213, noise power included in the receive signal, and prior information obtained from the bit-reduction decoder 215.

The de-mapper 214 performs processing with respect to a signal mapped by the mapper 204. In other words, the de-mapper 214 calculates LLRs for a bit sequence (corresponding to the bit sequence m illustrated in FIG. 4 and FIG. 5) after bit number reduction processing is performed at a transmit apparatus side.

In a subsequent step of decoding processing (decoder 217) processing is performed with respect to all coding bits (corresponding to the bit sequence b illustrated in FIG. 4 and FIG. 5), and therefore conversion of LLRs post-bit-reduction (LLRs pertaining to processing of the de-mapper 214) to LLRs pre-bit-reduction (LLRs pertaining to processing of the decoder 217) is required.

Thus, at the bit-reduction decoder 215, LLRs post-bit-reduction inputted from the de-mapper 214 are converted to LLRs corresponding to a time pre-bit-reduction (corresponding to bit sequence b illustrated in FIG. 4 and FIG. 5). Details of processing are described later.

An LLR calculated at the bit-reduction decoder 215 is inputted to the decoder 217 after de-interleaving processing by the de-interleaver 216. The decoder 217 performs decoding processing on the basis of inputted LLRs, and thereby re-calculates the LLRs. LLRs calculated by the decoder 217 are fed back to the bit-reduction decoder 215 after interleaving processing by the interleaver 218. The bit-reduction decoder 215 converts LLRs fed back from the decoder 217 to LLRs post-bit-reduction, and inputs the LLRs post-bit-reduction to the de-mapper 214. The de-mapper 214 again calculates an LLR for each bit, based on the receive signal, noise power included in the receive signal, and prior information obtained from the bit-reduction decoder 215.

In a case in which bit number reduction processing is not performed at a transmit apparatus side, the processing specific to the bit-reduction decoder 215 is not performed.

By repeatedly performing the above processing, finally a desired decoded result is obtained.

The following describes LLR calculation processing at the de-mapper 214.

An LLR outputted from the de-mapper 214 when a bit sequence b(b₀, b₁, . . . , b_(N−1)) of N (N being an integer greater than or equal to one) bits is allocated to M (M being an integer greater than or equal to one) symbol points S_(k)(S₀, S₁, . . . , S_(M−1)) is considered below.

When a receive signal is y, an i-th (i being an integer from zero to N−1) bit is b_(i), and an LLR for b_(i) is L(b_(i)), Math (1) holds true.

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 1} \right\rbrack & \; \\ \begin{matrix} {{L\left( b_{i} \right)} = {\log\frac{p\left( {b_{i} = {0❘y}} \right)}{p\left( {b_{i} = {1❘y}} \right)}}} \\ {= {\log\frac{{p\left( {{y❘b_{i}} = 0} \right)}{{p\left( {b_{i} = 0} \right)}/{p(y)}}}{{p\left( {{y❘b_{i}} = 1} \right)}{{p\left( {b_{i} = 1} \right)}/{p(y)}}}}} \\ {= {{\log\frac{p\left( {{y❘b_{i}} = 0} \right)}{p\left( {{y❘b_{i}} = 1} \right)}} + {\log\frac{p\left( {b_{i} = 0} \right)}{p\left( {b_{i} = 1} \right)}}}} \end{matrix} & \left( {{Math}\mspace{14mu} 1} \right) \end{matrix}$

As described later, the first term on the right side of the bottom formula shown in Math (1) is an LLR obtainable from a bit other than an i-th bit, and this is defined as extrinsic information L_(e)(b_(i)). Further, the second term on the right side of the bottom formula shown in Math (1) is an LLR obtainable based on a prior probability of an i-th bit, and this is defined as prior information L_(a)(b_(i)).

Thus, Math (1) becomes Math (2), and transformation to Math (3) is possible.

[Math 2] L(b _(i))=L _(e)(b _(i))+L _(a)(b _(i))  (Math 2) [Math 3] L _(e)(b _(i))L _(e)(b _(i))−L _(a)(b _(i))  (Math 3)

The de-mapper 214 outputs a processing result of Math (3) as an LLR.

The numerator p(y|b_(i)=0) of the first term on the right side of the bottom formula of Math (1) is considered below.

The numerator p(y|b_(i)=0) is a probability that a receive signal is y when b_(i)=0 is known. This is expressed in the product p(y|S_(k))p(S_(k)|b_(i)=0) of “a probability p(S_(k)|b_(i)=0) of a symbol point S_(k) when b_(i)=0 is known,” and “a probability p(y|S_(k)) of y when S_(k) is known”. When considering all symbol points, Math (4) holds true.

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 4} \right\rbrack & \; \\ {{p\left( {{y❘b_{i}} = 0} \right)} = {\sum\limits_{{S_{k}❘{S_{k}{(b_{i})}}} = 0}\;{{p\left( {y❘S_{k}} \right)}{p\left( {{S_{k}❘b_{i}} = 0} \right)}}}} & \left( {{Math}\mspace{14mu} 4} \right) \end{matrix}$

In the same way, with respect to the denominator p(y|b_(i)=1) of the first term on the right side of the bottom formula of Math (1), Math (5) holds true.

Accordingly, the first term on the right side of the bottom formula of Math (1) becomes Math (6).

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 5} \right\rbrack & \; \\ {{p\left( {{y❘b_{i}} = 1} \right)} = {\sum\limits_{{S_{k}❘{S_{k}{(b_{i})}}} = 1}{{p\left( {y❘S_{k}} \right)}{p\left( {{S_{k}❘b_{i}} = 1} \right)}}}} & \left( {{Math}\mspace{14mu} 5} \right) \\ \left\lbrack {{Math}\mspace{14mu} 6} \right\rbrack & \; \\ \begin{matrix} {{L_{e}\left( b_{i} \right)} = {\log\frac{p\left( {{y❘b_{i}} = 0} \right)}{p\left( {{y❘b_{i}} = 1} \right)}}} \\ {= {\log\frac{\sum\limits_{{S_{k}❘{S_{k}{(b_{i})}}} = 0}{{p\left( {y❘S_{k}} \right)}{p\left( {{S_{k}❘b_{i}} = 0} \right)}}}{\sum\limits_{{S_{k}❘{S_{k}{(b_{i})}}} = 1}{{p\left( {y❘S_{k}} \right)}{p\left( {{S_{k}❘b_{i}} = 1} \right)}}}}} \end{matrix} & \left( {{Math}\mspace{14mu} 6} \right) \end{matrix}$

The expression p(y|S_(k)) of Math (6) can be expressed as shown in Math (7) when Gaussian noise of variance σ² is added in the process of transmitting the symbol point S_(k) to become the receive signal y.

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 7} \right\rbrack & \; \\ {{p\left( {y❘S_{k}} \right)} = {\frac{1}{\sqrt{2\;\pi\;\sigma^{2}}}{\exp\left( {- \frac{\left( {y - S_{k}} \right)^{2}}{2\;\sigma^{2}}} \right)}}} & \left( {{Math}\mspace{14mu} 7} \right) \end{matrix}$

Further, the expression p(S_(k)|b_(i)=0) of Math (6) is a probability of the symbol point S_(k) when b_(i)=0 is known, and is expressed as a product of prior probabilities of bits other than b_(i) that constitute the symbol point S_(k). When a j-th (j=0, 1, . . . , N−1 (j being an integer from 0 to N−1)) bit of the symbol point S_(k) is expressed as S_(k)(b_(j)), Math (8) holds true.

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 8} \right\rbrack & \; \\ {{{S_{k}\left( b_{j} \right)} \in \left\{ {0,1} \right\}}{{p\left( {{S_{k}❘b_{i}} = 0} \right)} = {\prod\limits_{j \neq i}{p\left( {b_{j} = {S_{k}\left( b_{j} \right)}} \right)}}}} & \left( {{Math}\mspace{14mu} 8} \right) \end{matrix}$

The term p(b_(j)=S_(k)(b_(j))) is considered below.

When L_(a)(b_(j)) is given as prior information, Math (9) is derived from the second term of the right side of the bottom formula of Math (1), and can be transformed to Math (10).

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 9} \right\rbrack & \; \\ {{L_{a}\left( b_{j} \right)} = {\log\frac{p\left( {b_{j} = 0} \right)}{p\left( {b_{j} = 1} \right)}}} & \left( {{Math}\mspace{14mu} 9} \right) \\ \left\lbrack {{Math}\mspace{14mu} 10} \right\rbrack & \; \\ {\frac{p\left( {b_{j} = 0} \right)}{p\left( {b_{j} = 1} \right)} = {\exp\left( {L_{a}\left( b_{j} \right)} \right)}} & \left( {{Math}\mspace{14mu} 10} \right) \end{matrix}$

Further, from the relationship p(b_(j)=0)+p(b_(j)=1)=1, Math (11) and Math (12) are derived.

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 11} \right\rbrack & \; \\ {{p\left( {b_{j} = 0} \right)} = \frac{\exp\left( {L_{a}\left( b_{j} \right)} \right)}{1 + {\exp\left( {L_{a}\left( b_{j} \right)} \right)}}} & \left( {{Math}\mspace{14mu} 11} \right) \\ \left\lbrack {{Math}\mspace{14mu} 12} \right\rbrack & \; \\ {{p\left( {b_{j} = 1} \right)} = \frac{1}{1 + {\exp\left( {L_{a}\left( b_{j} \right)} \right)}}} & \left( {{Math}\mspace{14mu} 12} \right) \end{matrix}$

Using this, Math (13) is derived, and Math (8) becomes Math (14).

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 13} \right\rbrack & \; \\ {{p\left( {b_{j} = {S_{k}\left( b_{j} \right)}} \right)} = \frac{\exp\left( {{- {S_{k}\left( b_{j} \right)}}{L_{a}\left( b_{j} \right)}} \right)}{1 + {\exp\left( {- {L_{a}\left( b_{j} \right)}} \right)}}} & \left( {{Math}\mspace{14mu} 13} \right) \\ \left\lbrack {{Math}\mspace{14mu} 14} \right\rbrack & \; \\ \begin{matrix} {{p\left( {{S_{k}❘b_{i}} = 0} \right)} = {\prod\limits_{j \neq i}{p\left( {b_{j} = {S_{k}\left( b_{j} \right)}} \right)}}} \\ {= {\prod\limits_{j \neq i}\frac{\exp\left( {{- {S_{k}\left( b_{j} \right)}}{L_{a}\left( b_{j} \right)}} \right)}{1 + {\exp\left( {- {L_{a}\left( b_{j} \right)}} \right)}}}} \end{matrix} & \left( {{Math}\mspace{14mu} 14} \right) \end{matrix}$

With respect to p(S_(k)|b_(i)=1), a formula similar to Math (14) is derived. From Math (7) and Math (14), Math (6) becomes Math (15). Note that as per the condition of Σ, the numerator of S_(k)(b_(i)) is zero, and the denominator of S_(k)(b_(i)) is one.

$\begin{matrix} {\mspace{79mu}\left\lbrack {{Math}\mspace{14mu} 15} \right\rbrack} & \; \\ \begin{matrix} {{L_{e}\left( b_{i} \right)} = {\log\frac{\sum\limits_{{S_{k}❘{S_{k}{(b_{i})}}} = 0}{{p\left( {y❘S_{k}} \right)}{p\left( {{S_{k}❘b_{i}} = 0} \right)}}}{\sum\limits_{{S_{k}❘{S_{k}{(b_{i})}}} = 1}{{p\left( {y❘S_{k}} \right)}{p\left( {{S_{k}❘b_{i}} = 1} \right)}}}}} \\ {= {\log\frac{\sum\limits_{{S_{k}❘{S_{k}{(b_{i})}}} = 0}{\frac{1}{\sqrt{2\;\pi\;\sigma^{2}}}{\exp\left( {- \frac{{{y - S_{k}}}^{2}}{2\;\sigma^{2}}} \right)}{\prod\limits_{j \neq i}\frac{\exp\left( {{- {S_{k}\left( b_{j} \right)}}{L_{a}\left( b_{j} \right)}} \right)}{1 + {\exp\left( {- {L_{a}\left( b_{j} \right)}} \right)}}}}}{\sum\limits_{{S_{k}❘{S_{k}{(b_{i})}}} = 1}{\frac{1}{\sqrt{2\;\pi\;\sigma^{2}}}{\exp\left( {- \frac{{{y - S_{k}}}^{2}}{2\;\sigma^{2}}} \right)}{\prod\limits_{j \neq i}\frac{\exp\left( {{- {S_{k}\left( b_{j} \right)}}{L_{a}\left( b_{j} \right)}} \right)}{1 + {\exp\left( {- {L_{a}\left( b_{j} \right)}} \right)}}}}}}} \\ {= {{\log\frac{\sum\limits_{{S_{k}❘{S_{k}{(b_{i})}}} = 0}{\exp\left( {{- \frac{{{y - S_{k}}}^{2}}{2\;\sigma^{2}}}{\sum\limits_{j}{{S_{k}\left( b_{j} \right)}{L_{a}\left( b_{j} \right)}}}} \right)}}{\sum\limits_{{S_{k}❘{S_{k}{(b_{i})}}} = 1}{\exp\left( {{- \frac{{{y - S_{k}}}^{2}}{2\;\sigma^{2}}} - {\sum\limits_{j}{{S_{k}\left( b_{j} \right)}{L_{a}\left( b_{j} \right)}}}} \right)}}} - {L_{a}\left( b_{i} \right)}}} \end{matrix} & \left( {{Math}\mspace{14mu} 15} \right) \end{matrix}$

From the above, in performing the repeated processing of BICM-ID, the de-mapper 214 performs exponential calculation and summation for a symbol point and each bit assigned to the symbol point, thereby seeking numerators/denominators, and further performs a logarithmic calculation.

The following described processing at the bit-reduction decoder 215.

The bit-reduction decoder 215 performs processing converting LLRs post-bit-reduction that are calculated at the de-mapper 214 to LLRs pre-bit-reduction that are required at the decoder 217, and performs processing converting LLRs pre-bit-reduction that are calculated at the decoder 217 to LLRs post-bit-reduction that are required at the de-mapper 214.

At the bit-reduction decoder 215, processing converting LLRs post-bit-reduction is performed at each [+] (each XOR section) in FIG. 5, calculation being performed according to bits connected to the [+].

In a configuration as illustrated in FIG. 6, L(u₃) is considered when L(u₁) and L(u₂) are given, each bit being defined as u₁, u₂, u₃, and each LLR for the bits being defined as L(u₁), L(u₂), L(u₃).

First, u₁ is considered below.

When L(u₁) is given, Math (16) and Math (17) are derived from Math (11) and Math (12).

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 16} \right\rbrack & \; \\ {{p\left( {u_{1} = 0} \right)} = \frac{\exp\left( {L\left( u_{1} \right)} \right)}{1 + {\exp\left( {L\left( u_{1} \right)} \right)}}} & \left( {{Math}\mspace{14mu} 16} \right) \\ \left\lbrack {{Math}\mspace{14mu} 17} \right\rbrack & \; \\ {{p\left( {u_{1} = 1} \right)} = \frac{1}{1 + {\exp\left( {L\left( u_{1} \right)} \right)}}} & \left( {{Math}\mspace{14mu} 17} \right) \end{matrix}$

When u₁=0 is associated with +1 and u₁=1 is associated with −1, the expected value E[u₁] of u₁ is defined as in Math (18).

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 18} \right\rbrack & \; \\ \begin{matrix} {{E\left\lbrack u_{1} \right\rbrack} = {{\left( {+ 1} \right){p\left( {u_{1} = 0} \right)}} + {\left( {- 1} \right){p\left( {u_{1} = 1} \right)}}}} \\ {= \frac{{\exp\left( {L\left( u_{1} \right)} \right)} - 1}{{\exp\left( {L\left( u_{1} \right)} \right)} + 1}} \\ {= {{\tanh\left( \frac{L\left( u_{1} \right)}{2} \right)}\left( {{\Theta\;{\tanh(\chi)}} = \frac{e^{\chi} - e^{- \chi}}{e^{\chi} + e^{- \chi}}} \right)}} \end{matrix} & \left( {{Math}\mspace{14mu} 18} \right) \end{matrix}$

In FIG. 6, u₃=u₁[+]u₂ and E[u₃]=E[u₁]E[u₂], and therefore when substituted into Math (18), Math (19) results, from which Math (20) is derived.

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 19} \right\rbrack & \; \\ {{\tanh\left( \frac{L\left( u_{3} \right)}{2} \right)} = {{\tanh\left( \frac{L\left( u_{1} \right)}{2} \right)}{\tanh\left( \frac{L\left( u_{2} \right)}{2} \right)}}} & \left( {{Math}\mspace{14mu} 19} \right) \\ \left\lbrack {{Math}\mspace{14mu} 20} \right\rbrack & \; \\ {{L\left( u_{3} \right)} = {2\;{\tanh^{- 1}\left( {{\tanh\left( \frac{L\left( u_{1} \right)}{2} \right)}{\tanh\left( \frac{L\left( u_{2} \right)}{2} \right)}} \right)}}} & \left( {{Math}\mspace{14mu} 20} \right) \end{matrix}$

The above considers bits u₁, u₂, and u₃, but when generalized to j signals, Math (21) is derived. For example, in FIG. 5, L(m₃), L(b₆), and L(b₅) are used when determining L(b₇), resulting in Math (22).

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 21} \right\rbrack & \; \\ {{L\left( u_{i} \right)} = {2\;{\tanh^{- 1}\left( {\prod\limits_{j❘{j \neq i}}{\tanh\left( \frac{L\left( u_{j} \right)}{2} \right)}} \right)}}} & \left( {{Math}\mspace{14mu} 21} \right) \\ \left\lbrack {{Math}\mspace{14mu} 22} \right\rbrack & \; \\ {{L\left( b_{7} \right)} = {2\;{\tanh^{- 1}\left( {\tanh\frac{L\left( m_{3} \right)}{2}\tanh\frac{L\left( b_{6} \right)}{2}\tanh\frac{L\left( b_{5} \right)}{2}} \right)}}} & \left( {{Math}\mspace{14mu} 22} \right) \end{matrix}$

In a case in which bit number reduction processing is not performed at a transmit apparatus side, the specific processing described above is not performed.

The above describes operations in connection with BICM-ID, but iterative detection need not be implemented, and signal processing may perform detection only once.

<Transmit Apparatus>

FIG. 7 illustrates a configuration of a transmit apparatus.

A transmit apparatus 700 includes an error correction coder 702, a control information generator and mapper 704, an interleaver 706, a mapper 708, a modulator 710, and a radio section 712.

The error correction coder 702 receives a control signal and information bits as input, determines, for example, code length (block length) of error correction code and coding rate of error correction code based on the control signal, performs error correction coding on the information bits based on a determined error correction coding method, and outputs bits after error correction coding to the interleaver 706.

The interleaver 706 receives a control signal and bits post-coding as input, determines an interleaving method based on the control signal, interleaves (permutes) the bits post-coding, and outputs data post-interleaving to the mapper 708.

The control information generator and mapper 704 receives a control signal as input, generates control information for a receive apparatus to operate (for example, information related to physical layers such as an error correction scheme or modulation scheme used by a transmit apparatus, control information not related to physical layers, etc.) based on the control signal, performs mapping on the control information, and outputs a control information signal.

The mapper 708 receives a control signal and data post-interleaving as input, determines a mapping method based on the control signal, performs mapping on the data post-interleaving according to the mapping method determined, and outputs a baseband signal in-phase component I and quadrature component Q. Modulation schemes that the mapper 708 is capable of supporting are, for example, π/2 shift BPSK, QPSK, 8PSK, (12,4)16APSK, (8,8)16APSK, and 32APSK.

Details of (12,4)16APSK, (8,8)16APSK, and details of a mapping method that is a feature of the present embodiment are described in detail later.

The modulator 710 receives a control signal, a control information signal, a pilot signal, and a baseband signal as input, determines frame configuration based on the control signal, generates, according to the frame configuration, a modulated signal from the control information signal, the pilot signal, and the baseband signal, and outputs the modulated signal.

The radio section 712 receives a modulated signal as input, performs processing such as bandlimiting using a root roll-off filter, quadrature modulation, frequency conversion, and amplification, and generates a transmit signal, the transmit signal being transmitted from an antenna.

<Constellation>

The following describes constellations and assignment (labelling) of bits to each constellation point of (12,4)16APSK and (8,8)16APSK mapping performed by the mapper 708, which is of importance in the present embodiment.

As illustrated in FIG. 8, constellation points of (12,4)16APSK mapping are arranged in two concentric circles having different radii (amplitude components) in the I-Q plane. In the present description, among the concentric circles, a circle having a larger radius R₂ is referred to as an “outer circle” and a circle having a smaller radius R₁ is referred to as an “inner circle”. A ratio of the radius R₂ to the radius R₁ is referred to as a “radius ratio” (or “ring ratio”). Note that here, R₁ is a real number, R₂ is a real number, R₁ is greater than zero, and R₂ is greater than zero. Further, R₁ is less than R₂.

Further, on the circumference of the outer circle are arranged twelve constellation points and on the circumference of the inner circle are arranged four constellation points. The (12,4) in (12,4)16APSK indicates that in the order of outer circle, inner circle, there are twelve and four constellation points, respectively.

Coordinates of each constellation point of (12,4)16APSK on the I-Q plane are as follows:

Constellation point 1-1 [0000] . . . (R₂ cos(π/4),R₂ sin(π/4))

Constellation point 1-2 [1000] . . . (R₂ cos(5π/12),R₂ sin(5π/12))

Constellation point 1-3 [1100] . . . (R₁ cos(π/4),R₁ sin(π/4))

Constellation point 1-4 [0100] . . . (R₂ cos(π/12),R₂ sin(π/12))

Constellation point 2-1 [0010] . . . (R₂ cos(3π/4),R₂ sin(3π/4))

Constellation point 2-2 [1010] . . . (R₂ cos(7π/12),R₂ sin(7π/12))

Constellation point 2-3 [1110] . . . (R₁ cos(3π/4),R₁ sin(3π/4))

Constellation point 2-4 [0110] . . . (R₂ cos(11π/12),R₂ sin(11π/12))

Constellation point 3-1 [0011] . . . (R₂ cos(−3π/4),R₂ sin(−3π/4))

Constellation point 3-2 [1011] . . . (R₂ cos(−7π/12),R₂ sin(−7π/12))

Constellation point 3-3 [1111] . . . (R₁ cos(−3π/4),R₁ sin(−3π/4))

Constellation point 3-4 [0111] . . . (R₂ cos(−11π/12),R₂ sin(−11π/12))

Constellation point 4-1 [0001] . . . (R₂ cos(−π/4),R₂ sin(−π/4))

Constellation point 4-2 [1001] . . . (R₂ cos(−5π/12),R₂ sin(−5π/12))

Constellation point 4-3 [1101] . . . (R₁ cos(−π/4),R₁ sin(−π/4))

Constellation point 4-4 [0101] . . . (R₂ cos(−π/12),R₂ sin(−π/12))

With respect to phase, the unit used is radians. Accordingly, for example, referring to R₂ cos(π/4), the unit of π/4 is radians. Hereinafter, the unit of phase is radians.

Further, for example, the following relationship is disclosed above:

Constellation point 1-1 [0000] . . . (R₂ cos(π/4),R₂ sin(π/4))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[0000], an in-phase component I and quadrature component Q of a baseband signal after mapping are defined as (I,Q)=(R₂ cos(π/4),R₂ sin(π/4)). As another example, the following relationship is disclosed above:

Constellation point 4-4 [0101] . . . (R₂ cos(−π/12),R₂ sin(−π/12))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[0101], an in-phase component I and quadrature component Q of a baseband signal after mapping are defined as (I,Q)=(R₂ cos(−π/12),R₂ sin(−π/12)).

This holds true for all of constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 3-1, constellation point 3-2, constellation point 3-3, constellation point 3-4, constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4.

As illustrated in FIG. 9, constellation points of (8,8)16APSK mapping are arranged in two concentric circles having different radii (amplitude components) in the I-Q plane. On the circumference of the outer circle are arranged eight constellation points and on the circumference of the inner circle are arranged eight constellation points. The (8,8) in (8,8)16APSK indicates that in the order of outer circle, inner circle, there are eight and eight constellation points, respectively. Further, as with (12,4)16APSK, among the concentric circles, the circle having a larger radius R₂ is referred to as the “outer circle” and the circle having a smaller radius R₁ is referred to as the “inner circle”. A ratio of the radius R₂ to the radius R₁ is referred to as a “radius ratio” (or “ring ratio”). Note that here, R₁ is a real number, R₂ is a real number, R₁ is greater than zero, and R₂ is greater than zero. Also, R₁ is less than R₂.

Coordinates of each constellation point of (8,8)16APSK on the I-Q plane are as follows:

Constellation point 1-1 [0000] . . . (R₁ cos(π/8),R₁ sin(π/8))

Constellation point 1-2 [0010] . . . (R₁ cos(3π/8),R₁ sin(3π/8))

Constellation point 1-3 [0110] . . . (R₁ cos(5π/8),R₁ sin(5π/8))

Constellation point 1-4 [0100] . . . (R₁ cos(7π/8),R₁ sin(7π/8))

Constellation point 1-5 [1100] . . . (R₁ cos(−7π/8),R₁ sin(−7π/8))

Constellation point 1-6 [1110] . . . (R₁ cos(−5π/8),R₁ sin(−5π/8))

Constellation point 1-7 [1010] . . . (R₁ cos(−3π/8),R₁ sin(−3π/8))

Constellation point 1-8 [1000] . . . (R₁ cos(−π/8),R₁ sin(−π/8))

Constellation point 2-1 [0001] . . . (R₂ cos(π/8),R₂ sin(π/8))

Constellation point 2-2 [0011] . . . (R₂ cos(3π/8),R₂ sin(3π/8))

Constellation point 2-3 [0111] . . . (R₂ cos(5π/8),R₂ sin(5π/8))

Constellation point 2-4 [0101] . . . (R₂ cos(7π/8),R₂ sin(7π/8))

Constellation point 2-5 [1101] . . . (R₂ cos(−7π/8),R₂ sin(−7π/8))

Constellation point 2-6 [1111] . . . (R₂ cos(−5π/8),R₂ sin(−5π/8))

Constellation point 2-7 [1011] . . . (R₂ cos(−3π/8),R₂ sin(−3π/8))

Constellation point 2-8 [1001] . . . (R₂ cos(−π/8),R₂ sin(−π/8))

For example, the following relationship is disclosed above:

Constellation point 1-1 [0000] . . . (R₁ cos(π/8),R₁ sin(π/8))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[0000], an in-phase component I and quadrature component Q of a baseband signal after mapping are defined as (I,Q)=(R₁ cos(π/8),R₁ sin(π/8)). As another example, the following relationship is disclosed above:

Constellation point 2-8 [1001] . . . (R₂ cos(−π/8),R₂ sin(−π/8))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[1001], an in-phase component I and quadrature component Q of a baseband signal after mapping are defined as (I,Q)=(R₂ cos(−π/8),R₂ sin(−π/8)).

This holds true for all of constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 1-5, constellation point 1-6, constellation point 1-7, constellation point 1-8, constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 2-5, constellation point 2-6, constellation point 2-7, and constellation point 2-8.

<Transmission Output>

In order to achieve the same transmission output for each of the two types of modulation scheme above, the following normalization coefficient may be used.

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 23} \right\rbrack & \; \\ {a_{({12,4})} = \frac{z}{\sqrt{\left( {{4 \times R_{1}^{2}} + {12 \times R_{2}^{2}}} \right)/16}}} & \left( {{Math}\mspace{14mu} 23} \right) \\ \left\lbrack {{Math}\mspace{14mu} 24} \right\rbrack & \; \\ {a_{({8,8})} = \frac{z}{\sqrt{\left( {R_{1}^{2} + R_{2}^{2}} \right)/2}}} & \left( {{Math}\mspace{14mu} 24} \right) \end{matrix}$

Note that a_((12,4)) is a normalization coefficient of (12,4)16APSK and a_((8,8)) is a coefficient of (8,8)16APSK.

Prior to normalization, the in-phase component of a baseband signal is I_(b) and the quadrature component of the baseband signal is Q_(b). After normalization, the in-phase component of the baseband signal is I_(n) and the quadrature component of the baseband signal is Q_(n). Thus, when a modulation scheme is (12,4)16APSK, (I_(n), Q_(n))=(a_((12,4))×I_(b), a_((12,4))×Q_(b)) holds true, and when a modulation scheme is (8,8)16APSK, (I_(n), Q_(n))=(a_((8,8))×I_(b), a_((8,8))×Q_(b)) holds true.

When a modulation scheme is (12,4)16APSK, the in-phase component I_(b) and quadrature component Q_(b) are the in-phase component I and quadrature component Q, respectively, of a baseband signal after mapping that is obtained by mapping based on FIG. 8. Accordingly, when a modulation scheme is (12,4)16APSK, the following relationships hold true:

-   -   Constellation point 1-1 [0000] . . . (I_(n),         Q_(n))=(a_((12,4))×R₂ cos(π/4), a_((12,4))×R₂×sin(π/4))     -   Constellation point 1-2 [1000] . . . (I_(n),         Q_(n))=(a_((12,4))×R₂×cos(5π/12), a_((12,4))×R₂×sin(5π/12))     -   Constellation point 1-3 [1100] . . . (I_(n),         Q_(n))=(a_((12,4))×R₁×cos(π/4), a_((12,4))×R₁×sin(π/4))     -   Constellation point 1-4 [0100] . . . (I_(n),         Q_(n))=(a_((12,4))×R₂×cos(π/12), a_((12,4))×R₂×sin(π/12))     -   Constellation point 2-1 [0010] . . . (I_(n),         Q_(n))=(a_((12,4))×R₂×cos(3π/4), a_((12,4))×R₂×sin(3π/4))     -   Constellation point 2-2 [1010] . . . (I_(n),         Q_(n))=(a_((12,4))×R₂×cos(7π/12), a_((12,4))R₂×sin(7π/12))     -   Constellation point 2-3 [1110]. . . (I_(n),         Q_(n))=(a_((12,4))×R₁×cos(3π/4), a_((12,4))×R₁×sin(3π/4))     -   Constellation point 2-4 [0110] . . . (I_(n),         Q_(n))=(a_((12,4))R₂×cos(11π/12), a_((12,4))×R₂×sin(11π/12))     -   Constellation point 3-1 [0011] . . . (I_(n),         Q_(n))=(a_((12,4))R₂×cos(−3π/4), a_((12,4))R₂×sin(−3π/4))     -   Constellation point 3-2 [1011] . . . (I_(n),         Q_(n))=(a_((12,4))R₂×cos(−7π/12), a_((12,4))×R₂×sin(−7π/12))     -   Constellation point 3-3 [1111] . . . (I_(n),         Q_(n))=(a_((12,4))R₁×cos(−3π/4), a_((12,4))×R₂×sin(−3π/4))     -   Constellation point 3-4 [0111] . . . (I_(n),         Q_(n))=(a_((12,4))×R₂×cos(−11π/12), a_((12,4))×R₂×sin(−11π/12))     -   Constellation point 4-1 [0001] . . . (I_(n),         Q_(n))=(a_((12,4))R₂×cos(−π/4), a_((12,4))R₂×sin(−7π/4))     -   Constellation point 4-2 [1001] . . . (I_(n),         Q_(n))=(a_((12,4))R₂×cos(−5π/12), a_((12,4))×R₂×sin(−5π/12))     -   Constellation point 4-3 [1101] . . . (I_(n),         Q_(n))=(a_((12,4))×R₁×cos(−π/4), a_((12,4))×R₁×sin(−π/4))     -   Constellation point 4-4 [0101] . . . (I_(n),         Q_(n))=(a_((12,4))×R₂×cos(−π/12), a_((12,4))×R₂×sin(−π/12))

For example, the following relationship is disclosed above:

-   -   Constellation point 1-1 [0000] . . . (I_(n),         Q_(n))=(a_((12,4))R₂×cos(π/4), a_((12,4))R₂×sin(π/4))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[0000], (I_(n), Q_(n))=(a_((12,4))R₂×cos(π/4), a_((12,4))×R₂×sin(π/4)).

As another example, the following relationship is disclosed above:

-   -   Constellation point 4-4 [0101] . . . (I_(n),         Q_(n))=(a_((12,4))R₂×cos(−π/12), a_((12,4))×R₂×sin(−π/12))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[0101], (I_(n), Q_(n))=(a_((12,4)) R₂×cos(−π/12), a_((12,4))×R₂×sin(−π/12)).

This holds true for all of constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 3-1, constellation point 3-2, constellation point 3-3, constellation point 3-4, constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4.

Thus, the mapper 708 outputs I_(n) and Q_(n), as described above, as an in-phase component and a quadrature component, respectively, of a baseband signal.

In a similar way, when a modulation scheme is (8,8)16APSK, the in-phase component I_(b) and quadrature component Q_(b) are the in-phase component I and quadrature component Q, respectively, of a baseband signal after mapping that is obtained by mapping based on FIG. 9. Accordingly, when a modulation scheme is (8,8)16APSK, the following relationships hold true:

-   -   Constellation point 1-1 [0000] . . . (I_(n),         Q_(n))=(a_((8,8))×R₁×cos(π/8), a_((8,8))×R₁×sin(π/8))     -   Constellation point 1-2 [0010] . . . (I_(n),         Q_(n))=(a_((8,8))×R₁×cos(3π/8), a_((8,8))R₁×sin(3π/8))     -   Constellation point 1-3 [0110] . . . (I_(n),         Q_(n))=(a_((8,8))R₁×cos(5π/8), a_((8,8))×R₁×sin(5π/8))     -   Constellation point 1-4 [0100] . . . (I_(n),         Q_(n))=(a_((8,8))×R₁×cos(7π/8), a_((8,8))×R₁×sin(7π/8))     -   Constellation point 1-5 [1100] . . . (I_(n),         Q_(n))=(a_((8,8))×R₁×cos(−7π/8), a_((8,8))×R₁×sin(−7π/8))     -   Constellation point 1-6 [1110] . . . (I_(n),         Q_(n))=(a_((8,8))×R₁×cos(−5π/8), a_((8,8))×R₁×sin(−5π/8))     -   Constellation point 1-7 [1010] . . . (I_(n),         Q_(n))=(a_((8,8))×R₁×cos(−3π/8), a_((8,8))×R₁×sin(−3π/8))     -   Constellation point 1-8 [1000] . . . (I_(n),         Q_(n))=(a_((8,8))×R₁×cos(−π/8), a_((8,8))×R₁×sin(−π/8))     -   Constellation point 2-1 [0001] . . . (I_(n),         Q_(n))=(a_((8,8))×R₂ cos(7π/8), a_((8,8))×R₂×sin(π/8))     -   Constellation point 2-2 [0011] . . . (I_(n), Q_(n))=(a_((8,8))R₂         cos(3π/8), a_((8,8))×R₂×sin(3π/8))     -   Constellation point 2-3 [0111] . . . (I_(n), Q_(n))=(a_((8,8))R₂         cos(5π/8), a_((8,8))×R₂×sin(5π/8))     -   Constellation point 2-4 [0101] . . . (I_(n),         Q_(n))=(a_((8,8))×R₂ cos(7π/8), a_((8,8))×R₂×sin(7π/8))     -   Constellation point 2-5 [1101] . . . (I_(n),         Q_(n))=(a_((8,8))×R₂ cos(−7π/8), a_((8,8))×R₂×sin(−7π/8))     -   Constellation point 2-6 [1111] . . . (I_(n),         Q_(n))=(a_((8,8))×R₂ cos(−5π/8), a_((8,8))×R₂×sin(−5π/8))     -   Constellation point 2-7 [1011] . . . (I_(n),         Q_(n))=(a_((8,8))×R₂ cos(−3π/8), a_((8,8))×R₂×sin(−3π/8))     -   Constellation point 2-8 [1001] . . . (I_(n),         Q_(n))=(a_((8,8))×R₂ cos(−7π/8), a_((8,8))×R₂×sin(−π/8))

For example, the following relationship is disclosed above:

-   -   Constellation point 1-1 [0000] . . . (I_(n),         Q_(n))=(a_((8,8))×R₁×cos(π/8), a_((8,8))×R₁×sin(π/8))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[0000], (I_(n), Q_(n))=(a_((8,8))×R₁×cos(π/8), a_((8,8))×R₁×sin(π/8)). As another example, the following relationship is disclosed above:

-   -   Constellation point 2-8 [1001] . . . (I_(n),         Q_(n))=(a_((8,8))×R₂×cos(−π/8), a_((8,8))×R₂×sin(−π/8))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[1001], (I_(n), Q_(n))=(a_((8,8))×R₂×cos(−π/8), a_((8,8))×R₂×sin(−π/8)).

This holds true for all of constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 1-5, constellation point 1-6, constellation point 1-7, constellation point 1-8, constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 2-5, constellation point 2-6, constellation point 2-7, and constellation point 2-8.

Thus, the mapper 708 outputs I_(n) and Q_(n), as described above, as an in-phase component and a quadrature component, respectively, of a baseband signal.

<Frame Configuration of Modulated Signal>

The following describes frame configuration of a modulated signal when the present embodiment is applied to advanced wide band digital satellite broadcasting.

FIG. 10 is a block diagram related to generation of a modulated signal. FIG. 11 illustrates a frame configuration of a modulated signal.

Note that the blocks related to modulated signal generation in FIG. 10 are the error correction coder 702, the control information generator and mapper 704, the interleaver 706, and the mapper 708 in FIG. 7, consolidated and re-drawn.

A transmission and multiplexing configuration control (TMCC) signal is a control signal for performing control related to transmission and multiplexing such as a plurality of transmission modes (modulation scheme/error correction coding rate). Further, a TMCC signal indicates assignment of a modulation scheme for each symbol (or slot composed from a plurality of symbols).

A selector 1001 in FIG. 10 switches contact 1 and contact 2 so that symbol sequences of modulated wave output are arranged as illustrated in FIG. 11. Specifically, switching is performed as follows.

During synchronous transmission: Contact 1=d, contact 2=e.

During pilot transmission: Contact 1=c, contact 2=selection from a to e according to modulation scheme assigned to slot (or symbol) (as an important point of the present invention, b1 and b2 may be alternately selected for each symbol—this point is described in detail later).

During TMCC transmission: Contact 1=b, contact 2=e.

During data transmission: Contact 1=a, contact 2=selection from a to e according to modulation scheme assigned to slot (or symbol) (as an important point of the present invention, b1 and b2 may be alternately (or regularly) selected for each symbol—this point is described in detail later).

Information for arrangement indicated in FIG. 11 is included in the control signal of FIG. 10.

The interleaver 706 performs bit interleaving (bit permuting) based on information in the control signal.

The mapper 708 performs mapping according to a scheme selected by the selector 1001 based on the information in the control signal.

The modulator 710 performs processing such as time division multiplexing/quadrature modulation and bandlimiting according to a root roll-off filter, and outputs a modulated wave.

<Example of Data Symbol Pertaining to Present Invention>

As described above, in advanced wide band digital satellite broadcasting, in an in-phase (I)-quadrature-phase (Q) plane, (12,4)16APSK is used as a modulation scheme that broadcasts 16 constellation points, in other words four bits by one symbol. One reason for this is that PAPR of (12,4)16APSK is, for example, less than PAPR of 16QAM and PAPR of (8,8)16APSK, and therefore average transmission power of radio waves transmitted from a broadcast station, i.e., a satellite, can be increased. Accordingly, although BER properties of (12,4)16APSK are worse than BER properties of 16QAM and (8,8)16APSK, when the point that average transmission power can be set higher is considered, the probability of achieving a wide reception area is high (this point is described in more detail above).

Accordingly, in an in-phase (I)-quadrature-phase (Q) plane, as long as a modulation scheme (or transmission method) having a low PAPR and good BER properties is used as a modulation scheme (or transmission method) having 16 constellation points, the probability of achieving a wide reception area is high. The present invention is an invention based on this point (note that “good BER properties” means that at a given SNR, a low BER is achieved).

An outline of a method of constructing a data symbol, which is one point of the present invention, is described below.

“In a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols.” (However, as described in modifications below, there is a transmission method that can obtain a similar effect to the above symbol arrangement even as a method that does not satisfy this outline.)

This point is explained with specific examples below.

The 136 symbols of Data#7855 in FIG. 11 are, as illustrated in FIG. 11, ordered along a time axis into “1st symbol”, “2nd symbol”, “3rd symbol”, . . . , “135th symbol”, and “136th symbol”.

A (12,4)16APSK modulation scheme is used for odd-numbered symbols, and an (8,8)16APSK modulation scheme is used for even-numbered symbols.

An example of data symbols is illustrated in FIG. 12. FIG. 12 illustrates six symbols among 136 symbols (from “51st symbol” to “56th symbol”). As illustrated in FIG. 12, among consecutive symbols, two types of modulation scheme are alternately used in an order (12,4)16APSK, (8,8)16APSK, (12,4)16APSK, (8,8)16APSK, (12,4)16APSK, (8,8)16APSK.

FIG. 12 illustrates the following.

When four bits [b₃b₂b₁b₀] transmitted as the “51st symbol” are [1100], an in-phase component and quadrature component of a baseband signal corresponding to the constellation point marked by a black circle (●) in FIG. 12 is transmitted by the transmit apparatus. (modulation scheme: (12,4)16APSK)

When four bits [b₃b₂b₁b₀] transmitted as the “52nd symbol” are [0101], an in-phase component and quadrature component of a baseband signal corresponding to the constellation point marked by a black circle (●) in FIG. 12 is transmitted by the transmit apparatus. (modulation scheme: (8,8)16APSK)

When four bits [b₃b₂b₁b₀] transmitted as the “53rd symbol” are [0011], an in-phase component and quadrature component of a baseband signal corresponding to the constellation point marked by a black circle (●) in FIG. 12 is transmitted by the transmit apparatus. (modulation scheme: (12,4)16APSK)

When four bits [b₃b₂b₁b₀] transmitted as the “54th symbol” are [0110], an in-phase component and quadrature component of a baseband signal corresponding to the constellation point marked by a black circle (●) in FIG. 12 is transmitted by the transmit apparatus. (modulation scheme: (8,8)16APSK)

When four bits [b₃b₂b₁b₀] transmitted as the “55th symbol” are [1001], an in-phase component and quadrature component of a baseband signal corresponding to the constellation point marked by a black circle (●) in FIG. 12 is transmitted by the transmit apparatus. (modulation scheme: (12,4)16APSK)

When four bits [b₃b₂b₁b₀] transmitted as the “56th symbol” are [0010], an in-phase component and quadrature component of a baseband signal corresponding to the constellation point marked by a black circle (●) in FIG. 12 is transmitted by the transmit apparatus. (modulation scheme: (8,8)16APSK)

Note that in the above example an “odd-numbered symbol=(12,4)16APSK and even-numbered symbol=(8,8)16APSK modulation scheme configuration” is described, but this may be an “even-numbered symbol=(8,8)16APSK and odd-numbered symbol=(12,4)16APSK modulation scheme configuration”.

Thus, a transmission method having a low PAPR and good BER properties is achieved, and because an average transmission power can be set high and BER properties are good, the probability of achieving a wide reception area is high.

<Advantage of Arranging Alternate Symbols of Different Modulation Schemes>

According to the present invention, among modulation schemes having 16 constellation points in an I-Q plane, and in particular (12,4)16APSK for which PAPR is low and (8,8)16APSK for which PAPR is slightly higher: “In a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols”.

When (8,8)16APSK symbols are arranged consecutively, PAPR becomes higher as (8,8)16APSK symbols continue. However, in order that (8,8)16APSK symbols are not consecutive, “in a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols”, and therefore there are no consecutive constellation points in connection with (8,8)16APSK. Thus, PAPR is influenced by (12,4)16APSK, for which PAPR is low, and an effect of suppressing PAPR is obtained.

In connection with BER properties, when (12,4)16APSK symbols are consecutive, BER properties are poor when performing BICM (or BICM-ID) but “in a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols”. Thus, BER properties are influenced by (8,8)16APSK, and an effect of improving BER properties is obtained.

In particular, in order to obtain the low PAPR mentioned above, setting of the ring ratio of (12,4)16APSK and the ring ratio of (8,8)16APSK is of importance.

According to R₁ and R₂ used in representing the constellation points in the I-Q plane of (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK represents R_((12,4))=R₂/R₁.

In the same way, according to R₁ and R₂ used in representing the constellation points in the I-Q plane of (8,8)16APSK, a ring ratio R_((8,8)) of (8,8)16APSK represents R_((8,8))=R₂/R₁.

Thus, an effect is obtained that “when R_((8,8))<R_((12,4)), the probability of further lowering PAPR is high”.

When “in a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols”, a modulation scheme likely to control peak power is (8,8)16APSK. Peak power generated by (8,8)16APSK is likely to increase as R_((8,8)) increases. Accordingly, in order to avoid increasing peak power, setting R_((8,8)) low is preferable. On the other hand, there is a high degree of freedom for R_((12,4)) of (12,4)16APSK as long as a value is set for which BER properties are good. Thus, it is likely that the relationship R_((8,8))<R_((12,4)) is preferable.

However, even when R_((8,8))>R_((12,4)), an effect of lowering PAPR of (8,8)16APSK can be obtained.

Accordingly, when focusing on improving BER properties, R_((8,8))>R_((12,4)) may be preferable.

The above-described relationship of ring ratios is also true for the modifications described later (<Patterns of switching modulation schemes, etc.>).

According to the embodiment described above, by alternately arranging symbols of different modulation schemes, PAPR is low and contribution is made towards providing improved data reception quality.

As stated above, an outline of the present invention is: “in a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols”. The following describes labelling and constellations of (12,4)16APSK, and labelling and constellations of (8,8)16APSK for increasing the probability of a receive apparatus obtaining high data reception quality.

<Labelling and Constellations of (12,4)16APSK>

[Labelling of (12,4)16APSK]

The following describes labelling of (12,4)16APSK. Labelling is the relationship between four bits [b₃b₂b₁b₀], which are input, and arrangement of constellation points in an in-phase (I)-quadrature-phase (Q) plane. An example of labelling of (12,4)16APSK is illustrated in FIG. 8, but labelling need not conform to FIG. 8 as long as labelling satisfies the following <Condition 1> and <Condition 2>.

For the purposes of description, the following definitions are used.

When four bits to be transmitted are [b_(a3)b_(a2)b_(a1)b_(a0)], a constellation point A is provided in the in-phase (I)-quadrature-phase (Q) plane, and when four bits to be transmitted are [b_(b3)b_(b2)b_(b1)b_(b0)], a constellation point B is provided in the in-phase (I)-quadrature-phase (Q) plane.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as zero.

Further, the following definitions are made.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as four.

Thus, group definitions are performed.

In labelling and constellation of (12,4)16APSK in an in-phase (I)-quadrature-phase (Q) plane in FIG. 8, constellation point 1-1, constellation point 1-2, constellation point 1-3, and constellation point 1-4 are defined as group 1. In the same way, constellation point 2-1, constellation point 2-2, constellation point 2-3, and constellation point 2-4 are defined as group 2; constellation point 3-1, constellation point 3-2, constellation point 3-3, and constellation point 3-4 are defined as group 3; and constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4 are defined as group 4.

The following two conditions are provided.

<Condition 1>

X represents 1, 2, 3, and 4. All values of X satisfy the following:

The number of different bits of labelling between constellation point X-1 and constellation point X-2 is one;

The number of different bits of labelling between constellation point X-2 and constellation point X-3 is one;

The number of different bits of labelling between constellation point X-3 and constellation point X-4 is one; and

The number of different bits of labelling between constellation point X-4 and constellation point X-1 is one.

<Condition 2>

In the outer circle:

The number of different bits of labelling between constellation point 1-2 and constellation point 2-2 is one;

The number of different bits of labelling between constellation point 3-2 and constellation point 4-2 is one;

The number of different bits of labelling between constellation point 1-4 and constellation point 4-4 is one; and

The number of different bits of labelling between constellation point 2-4 and constellation point 3-4 is one.

In the inner circle:

The number of different bits of labelling between constellation point 1-3 and constellation point 2-3 is one;

The number of different bits of labelling between constellation point 2-3 and constellation point 3-3 is one;

The number of different bits of labelling between constellation point 3-3 and constellation point 4-3 is one; and

The number of different bits of labelling between constellation point 4-3 and constellation point 1-3 is one.

By satisfying the above conditions, the number of different bits of labelling among constellation points that are near each other in an in-phase (I)-quadrature-phase (Q) plane is low, and therefore the possibility of a receive apparatus achieving high data reception quality is increased. Thus, when a receive apparatus performs iterative detection, the possibility of the receive apparatus achieving high data reception quality is increased.

Constellation of (12,4)16APSK

The above describes constellation and labelling in an in-phase (I)-quadrature-phase (Q) plane of FIG. 14, but constellation and labelling in an in-phase (I)-quadrature-phase (Q) plane is not limited to this example. For example, labelling of coordinates on an I-Q plane of each constellation point of (12,4)16APSK may be performed as follows.

Coordinates on an I-Q plane of the constellation point 1-1: (cos θ×R₂×cos(π/4)−sin θ×R₂×sin(π/4), sin θ×R₂×cos(π/4)+cos θ×R₂×sin(π/4))

Coordinates on an I-Q plane of the constellation point 1-2: (cos θ×R₂×cos(5π/12)−sin θ×R₂×Sin(5π/12), sin θ×R₂×cos(5π/12)+cos θ×R₂×sin(5π/12))

Coordinates on an I-Q plane of the constellation point 1-3: (cos θ×R₁×cos(π/4)−sin θ×R₁×sin(π/4), sin θ×R₁×cos(π/4)+cos θ×R₁×sin(π/4))

Coordinates on an I-Q plane of the constellation point 1-4: (cos θ×R₂ cos(π/12)−sin θ×R₂×sin(π/12), sin θ×R₂ cos(π/12)+cos θ×R₂×sin(π/12))

Coordinates on an I-Q plane of the constellation point 2-1: (cos θ×R₂×cos(3π/4)−sin θ×R₂×sin(3π/4), sin θ×R₂ cos(3π/4)+cos θ×R₂×sin(3π/4))

Coordinates on an I-Q plane of the constellation point 2-2: (cos θ×R₂ cos(7π/12)−sin θ×R₂×sin(7π/12), sin θ×R₂×cos(7π/12)+cos θ×R₂×sin(7π/12))

Coordinates on an I-Q plane of the constellation point 2-3: (cos θ×R₁×cos(3π/4)−sin θ×R₁×sin(3π/4), sin θ×R₁×cos(3π/4)+cos θ×R₁×sin(3π/4))

Coordinates on an I-Q plane of the constellation point 2-4: (cos θ×R₂×cos(11π/12)−sin θ×R₂×sin(11π/12), sin θ×R₂ cos(11π/12)+cos θ×R₂×sin(11π/12))

Coordinates on an I-Q plane of the constellation point 3-1: (cos θ×R₂×cos(−3π/4)−sin θ×R₂×sin(−3π/4), sin θ×R₂×cos(−3π/4)+cos θλR₂×sin(−3π/4))

Coordinates on an I-Q plane of the constellation point 3-2: (cos θ×R₂×cos(−7π/12)−sin θ×R₂×Sin(−7π/12), sin θ×R₂×cos(−7π/12)+cos θ×R₂×sin(−7π/12))

Coordinates on an I-Q plane of the constellation point 3-3: (cos θ×R₁×cos(−3π/4)−sin θ×R₁×sin(−3π/4), sin θ×R₁×cos(−3π/4)+cos θ×R₁×sin(−3π/4))

Coordinates on an I-Q plane of the constellation point 3-4: (cos θ×R₂×cos(−11π/12)−sin θ×R₂×sin(−11π/12), sin θ×R₂×cos(−11π/12)+cos θ×R₂×sin(−11π/12))

Coordinates on an I-Q plane of the constellation point 4-1: (cos θ×R₂×cos(−π/4)−sin θ×R₂×sin(−π/4), sin θ×R₂×cos(−π/4)+cos θ×R₂×sin(−π/4))

Coordinates on an I-Q plane of the constellation point 4-2: (cos θ×R₂×cos(−5π/12)−sin θ×R₂×sin(−5π/12), sin θ×R₂×cos(−5π/12)+cos θ×R₂×sin(−5π/12))

Coordinates on an I-Q plane of the constellation point 4-3: (cos θ×R₁×cos(−π/4)−sin θ×R₁×sin(−π/4), sin θ×R₁×cos(−π/4)+cos θ×R₁×sin(−π/4))

Coordinates on an I-Q plane of the constellation point 4-4: (cos θ×R₂×cos(−π/12)−sin θ×R₂×sin(−π/12), sin θ×R₂×cos(−π/12)+cos θ×R₂×sin(−π/12))

With respect to phase, the unit used is radians. Accordingly, an in-phase component I_(n) and a quadrature component Q_(n) of a baseband signal after normalization is represented as below.

Coordinates on an I-Q plane of the constellation point 1-1: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(π/4)−a_((12,4))×sin θ×R₂×sin(π/4), a_((12,4))×sin θ×R₂ cos(π/4)+a_((12,4))×cos θ×R₂×sin(π/4))

Coordinates on an I-Q plane of the constellation point 1-2: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(5π/12)−a_((12,4))×sin θ×R₂×sin(5π/12), a_((12,4))×sin θ×R₂×cos(5π/12)+a_((12,4))×cos θ×R₂×sin(5π/12))

Coordinates on an I-Q plane of the constellation point 1-3: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₁×cos(π/4)−a_((12,4))×sin θ×R₁×sin(π/4), a_((12,4))×sin θ×R₁×cos(π/4)+a_((12,4))×cos θ×R₁×sin(π/4))

Coordinates on an I-Q plane of the constellation point 1-4: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(π/12)−a_((12,4))×sin θ×R₂×sin(π/12), a_((12,4))×sin θ×R₂×cos(π/12)+a_((12,4))×cos θ×R₂×sin(π/12))

Coordinates on an I-Q plane of the constellation point 2-1: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(3π/4)−a_((12,4))×sin θ×R₂×sin(3π/4), a_((12,4))×sin θ×R₂×cos(3π/4)+a_((12,4))×cos θ×R₂×sin(3π/4))

Coordinates on an I-Q plane of the constellation point 2-2: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(7π/12)−a_((12,4))×sin θ×R₂×sin(7π/12), a_((12,4))×sin θ×R₂×cos(7π/12)+a_((12,4))×cos θ×R₂×sin(7π/12))

Coordinates on an I-Q plane of the constellation point 2-3: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₁×cos(3π/4)−a_((12,4))×sin θ×R₁×sin(3π/4), a_((12,4))×sin θ×R₁×cos(3π/4)+a_((12,4))×cos θ×R₁×sin(3π/4))

Coordinates on an I-Q plane of the constellation point 2-4: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(11π/12)−a_((12,4))×sin θ×R₂×sin(11π/12), a_((12,4))×sin θ×R₂×cos(11π/12)+a_((12,4))×cos θ×R₂×sin(11π/12))

Coordinates on an I-Q plane of the constellation point 3-1: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(−3π/4)−a_((12,4))×sin θ×R₂×sin(−3π/4), a_((12,4))×sin θ×R₂×cos(−3π/4)+a_((12,4))×cos θ×R₂×sin(−3π/4))

Coordinates on an I-Q plane of the constellation point 3-2: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(−7π/12)−a_((12,4))×sin θ×R₂×sin(−7π/12), a_((12,4))×sin θ×R₂×cos(−7π/12)+a_((12,4))×cos θ×R₂×sin(−7π/12))

Coordinates on an I-Q plane of the constellation point 3-3: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₁×cos(−3π/4)−a_((12,4))×sin θ×R₁×sin(−3π/4), a_((12,4))×sin θ×R₁×cos(−3π/4)+a_((12,4))×cos θ×R₁×sin(−3π/4))

Coordinates on an I-Q plane of the constellation point 3-4: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(−11π/12)−a_((12,4))×sin θ×R₂×sin(−11π/12), a_((12,4))×sin θ×R₂ cos(−11π/12)+a_((12,4))×cos θ×R₂×sin(−11π/12))

Coordinates on an I-Q plane of the constellation point 4-1: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(−π/4)−a_((12,4)) sin θ×R₂×sin(−π/4), a_((12,4))×sin θ×R₂×cos(−π/4)+a_((12,4))×cos θ×R₂×sin(−π/4))

Coordinates on an I-Q plane of the constellation point 4-2: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(−5π/12)−a_((12,4))×sin θ×R₂×sin(−5π/12), a_((12,4)) sin θ×R₂×cos(−5π/12)+a_((12,4))×cos θ×R₂×sin(−5π/12))

Coordinates on an I-Q plane of the constellation point 4-3: (I_(n), Q_(n))=(a_((12,4))×cos R₁×cos(−π/4)−a_((12,4))×sin θ×R₁×sin(−π/4), a_((12,4))×sin θ×R₁×cos(−π/4)+a_((12,4))×cos θ×R₁×sin(−π/4))

Coordinates on an I-Q plane of the constellation point 4-4: (I_(n), Q_(n))=(a_((12,4))×cos θ×R₂×cos(−π/12)−a_((12,4))×sin θ×R₂×sin(−π/12), a_((12,4))×sin θ×R₂×cos(−π/12)+a_((12,4))×cos θ×R₂×sin(−π/12))

Note that θ is a phase provided on an in-phase (I)-quadrature-phase (Q) plane, and a_((12,4)) is as shown in Math (23).

In a scheme wherein “in a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols”, a (12,4)16APSK modulation scheme may be used for which coordinates on an I-Q plane of each constellation point are as described above and <Condition 1> and <Condition 2> are satisfied.

One example that satisfies the above is an example of constellation and labelling of (12,4)16APSK illustrated in FIG. 15. FIG. 15 shows every constellation point rotated π/6 radians with respect to FIG. 14, so that θ=π/6.

<Labelling and Constellations of (8,8)16APSK>

[Labelling of (8,8)16APSK]

The following describes labelling of (8,8)16APSK. An example of labelling of (8,8)16APSK is illustrated in FIG. 9, but labelling need not conform to FIG. 9 as long as labelling satisfies the following <Condition 3> and <Condition 4>.

For the purposes of description, the following definitions are used.

As illustrated in FIG. 16, eight constellation points on the circumference of the inner circle are defined as group 1: constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 1-5, constellation point 1-6, constellation point 1-7, and constellation point 1-8. Further, eight constellation points on the circumference of the outer circle are defined as group 2: constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 2-5, constellation point 2-6, constellation point 2-7, and constellation point 2-8.

The following two conditions are provided.

<Condition 3>

X represents 1 and 2. All values of X satisfy the following:

The number of different bits of labelling between constellation point X-1 and constellation point X-2 is one.

The number of different bits of labelling between constellation point X-2 and constellation point X-3 is one.

The number of different bits of labelling between constellation point X-3 and constellation point X-4 is one.

The number of different bits of labelling between constellation point X-4 and constellation point X-5 is one.

The number of different bits of labelling between constellation point X-5 and constellation point X-6 is one.

The number of different bits of labelling between constellation point X-6 and constellation point X-7 is one.

The number of different bits of labelling between constellation point X-7 and constellation point X-8 is one.

The number of different bits of labelling between constellation point X-8 and constellation point X-1 is one.

Definitions of the number of different bits of labelling are as described above.

<Condition 4>

Z represents 1, 2, 3, 4, 5, 6, 7, and 8. All values of Z satisfy the following:

The number of different bits of labelling between constellation point 1-Z and constellation point 2-Z is one.

By satisfying the above conditions, the number of different bits of labelling among constellation points that are near each other in an in-phase (I)-quadrature-phase (Q) plane is low, and therefore the possibility of a receive apparatus achieving high data reception quality is increased. Thus, when a receive apparatus performs iterative detection, the possibility of the receive apparatus achieving high data reception quality is increased.

Constellation of (8,8)16APSK

The above describes constellation and labelling in an in-phase (I)-quadrature-phase (Q) plane of FIG. 16, but constellation and labelling in an in-phase (I)-quadrature-phase (Q) plane is not limited to this example. For example, coordinates on an I-Q plane of each constellation point of (8,8)16APSK may be labelled as follows.

Coordinates on an I-Q plane of the constellation point 1-1: (cos θ×R₁×cos(π/8)−sin θ×R₁×sin(π/8), sin θ×R₁×cos(π/8)+cos θ×R₁×sin(π/8))

Coordinates on an I-Q plane of the constellation point 1-2: (cos θ×R₁×cos(3π/8)−sin θ×R₁×sin(3π/8), sin θ×R₁×cos(3π/8)+cos θ×R₁×sin(3π/8))

Coordinates on an I-Q plane of the constellation point 1-3: (cos θ×R₁×cos(5π/8)−sin θ×R₁×sin(5π/8), sin θ×R₁×cos(5π/8)+cos θ×R₁×sin(5π/8))

Coordinates on an I-Q plane of the constellation point 1-4: (cos θ×R₁×cos(7π/8)−sin θ×R₁×sin(7π/8), sin θ×R₁×cos(7π/8)+cos θ×R₁×sin(7π/8))

Coordinates on an I-Q plane of the constellation point 1-5: (cos θ×R₁×cos(−7π/8)−sin θ×R₁×sin(−7π/8), sin θ×R₁×cos(−7π/8)+cos θ×R₁×sin(−7π/8))

Coordinates on an I-Q plane of the constellation point 1-6: (cos θ×R₁×cos(−5π/8)−sin θ×R₁×sin(−5π/8), sin θ×R₁×cos(−5π/8)+cos θ×R₁×sin(−5π/8))

Coordinates on an I-Q plane of the constellation point 1-7: (cos θ×R₁×cos(−3π/8)−sin θ×R₁×sin(−3π/8), sin θ×R₁×cos(−3π/8)+cos θ×R₁×sin(−3π/8))

Coordinates on an I-Q plane of the constellation point 1-8: (cos θ×R₁×cos(−π/8)−sin θ×R₁×sin(−π/8), sin θ×R₁×cos(−π/8)+cos θ×R₁×sin(−π/8)

Coordinates on an I-Q plane of the constellation point 2-1: (cos θ×R₂×cos(π/8)−sin θ×R₁×sin(π/8), sin θ×R₂×cos(π/8)+cos θ×R₂×sin(π/8))

Coordinates on an I-Q plane of the constellation point 2-2: (cos θ×R₂×cos(3π/8)−sin θ×R₂×sin(3π/8), sin θ×R₂×cos(3π/8)+cos θ×R₂×sin(3π/8))

Coordinates on an I-Q plane of the constellation point 2-3: (cos θ×R₂×cos(5π/8)−sin θ×R₂×sin(5π/8), sin θ×R₂×cos(5π/8)+cos θ×R₂×sin(5π/8))

Coordinates on an I-Q plane of the constellation point 2-4: (cos θ×R₂×cos(7π/8)−sin θ×R₂×sin(7π/8), sin θ×R₂×cos(7π/8)+cos θ×R₂×sin(7π/8))

Coordinates on an I-Q plane of the constellation point 2-5: (cos θ×R₂×cos(−7π/8)−sin θ×R₂×sin(−7π/8), sin θ×R₂×cos(−7π/8)+cos θ×R₂×sin(−7π/8))

Coordinates on an I-Q plane of the constellation point 2-6: (cos θ×R₂×cos(−5π/8)−sin θ×R₂×sin(−5π/8), sin θ×R₂×cos(−5π/8)+cos θ×R₂×sin(−5π/8))

Coordinates on an I-Q plane of the constellation point 2-7: (cos θ×R₂×cos(−3π/8)−sin θ×R₂×sin(−3π/8), sin θ×R₂×cos(−3π/8)+cos θ×R₂×sin(−3π/8))

Coordinates on an I-Q plane of the constellation point 2-8: (cos θ×R₂×cos(−π/8)−sin θ×R₂×sin(−π/8), sin θ×R₂×cos(−π/8)+cos θ×R₂×sin(−π/8))

With respect to phase, the unit used is radians. Accordingly, an in-phase component I_(n) and a quadrature component Q_(n) of a baseband signal after normalization is represented as below.

Coordinates on an I-Q plane of the constellation point 1-1: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₁×cos(π/8)−a_((8,8)) sin θ×R₁×sin(π/8), a_((8,8))×sin θ×R₁×cos(π/8)+a_((8,8))×cos θ×R₁×sin(π/8))

Coordinates on an I-Q plane of the constellation point 1-2: (I_(n), Q_(n))=(a_((8,8))×cos R₁×cos(3π/8)−a_((8,8))×sin θ×R₁×sin(3π/8), a_((8,8))×sin θ×R₁×cos(3π/8)+a_((8,8))×cos θ×R₁×sin(3π/8))

Coordinates on an I-Q plane of the constellation point 1-3: (I_(n), Q_(n))=(a_((8,8))×cos R₁×cos(5π/8)−a_((8,8))×sin θ×R₁×sin(5π/8), a_((8,8))×sin θ×R₁×cos(5π/8)+a_((8,8))×cos θ×R₁×sin(5π/8))

Coordinates on an I-Q plane of the constellation point 1-4: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₁×cos(7π/8)−a_((8,8))×sin θ×R₁×sin(7π/8), a_((8,8))×sin θ×R₁×cos(7π/8)+a_((8,8))×cos θ×R₁×sin(7π/8))

Coordinates on an I-Q plane of the constellation point 1-5: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₁×cos(−7π/8)−a_((8,8))×sin θ×R₁×sin(−7π/8), a_((8,8))×sin θ×R₁×cos(−7π/8)+a_((8,8))×cos θ×R₁ sin(−7π/8))

Coordinates on an I-Q plane of the constellation point 1-6: (I_(n), Q_(n))=(a_((8,8)) cos θ×R₁×cos(−5π/8)−a_((8,8))×sin θ×R₁×sin(−5π/8), a_((8,8))×sin θ×R₁×cos(−5π/8)+a_((8,8))×cos θ×R₁×sin(−5π/8))

Coordinates on an I-Q plane of the constellation point 1-7: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₁×cos(−3π/8)−a_((8,8))×sin θ×R₁×sin(−3π/8), a_((8,8))×sin θ×R₁×cos(−3π/8)+a_((8,8))×cos θ×R₁×sin(−3π/8))

Coordinates on an I-Q plane of the constellation point 1-8: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₁×cos(−π/8)−a_((8,8))×sin θ×R₁×sin(−π/8), a_((8,8))×sin θ×R₁×cos(−π/8)+a_((8,8))×cos θ×R₁×sin(−π/8))

Coordinates on an I-Q plane of the constellation point 2-1: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₂×cos(π/8)−a_((8,8)) sin θ×R₂×sin(π/8), a_((8,8))×sin θ×R₂×cos(π/8)+a_((8,8))×cos θ×R₂×sin(π/8))

Coordinates on an I-Q plane of the constellation point 2-2: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₂×cos(3π/8)−a_((8,8))×sin θ×R₂×sin(3π/8), a_((8,8))×sin θ×R₂×cos(3π/8)+a_((8,8))×cos θ×R₂×sin(3π/8))

Coordinates on an I-Q plane of the constellation point 2-3: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₂×cos(5π/8)−a_((8,8))×sin θ×R₂×sin(5π/8), a_((8,8))×sin θ×R₂×cos(5π/8)+a_((8,8))×cos θ×R₂×sin(5π/8))

Coordinates on an I-Q plane of the constellation point 2-4: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₂×cos(7π/8)−a_((8,8))×sin θ×R₂×sin(7π/8), a_((8,8))×sin θ×R₂×cos(7π/8)+a_((8,8))×cos θ×R₂×sin(7π/8))

Coordinates on an I-Q plane of the constellation point 2-5: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₂×cos(−7π/8)−a_((8,8))×sin θ×R₂×sin(−7π/8), a_((8,8))×sin θ×R₂×cos(−7π/8)+a_((8,8))×cos θR₂×sin(−7π/8))

Coordinates on an I-Q plane of the constellation point 2-6: (I_(n), Q_(n))=(a_((8,8)) cos R₂×cos(−5π/8)−a_((8,8))×sin θ×R₂×sin(−5π/8), a_((8,8))×sin θ×R₂×cos(−5π/8)+a_((8,8))×cos θ×R₂×sin(−5π/8))

Coordinates on an I-Q plane of the constellation point 2-7: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₂×cos(−3π/8)−a_((8,8))×sin θ×R₂×sin(−3π/8), a_((8,8))×sin θ×R₂×cos(−3π/8)+a_((8,8))×cos θ×R₂×sin(−3π/8))

Coordinates on an I-Q plane of the constellation point 2-8: (I_(n), Q_(n))=(a_((8,8))×cos θ×R₂×cos(−π/8)−a_((8,8))×sin θ×R₂×sin(−π/8), a_((8,8))×sin θ×R₂×cos(−π/8)+a_((8,8))×cos θ×R₂×sin(−π/8))

Note that θ is a phase provided on an in-phase (I)-quadrature-phase (Q) plane, and a_((8,8)) is as shown in Math (24).

In a scheme wherein “in a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols”, an (8,8)16APSK modulation scheme may be used for which coordinates on an I-Q plane of each constellation point are as described above and <Condition 3> and <Condition 4> are satisfied.

Further, in a scheme wherein “in a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols”, according to the above description, when θ of (12,4)16APSK is θ=(N×π)/2 radians (N being an integer) and θ of (8,8)16APSK is θ=π/8+(N×π)/4 radians (N being an integer), there is a possibility that PAPR becomes lower. FIG. 17 is an example of constellation and labelling when θ=π/8 radians.

<Patterns of Switching Modulation Schemes, Etc.>

In the example of FIG. 12, an example is described in which (12,4)16APSK symbols and (8,8)16APSK symbols are alternately switched (there are no consecutive (12,4)16APSK symbols or consecutive (8,8)16APSK symbols). The following describes modifications of the above scheme.

FIG. 23 and FIG. 24 are related to modifications.

Features of the modifications are as follows.

-   -   One period (cycle) is composed of M symbols. Note that for the         following description, one period (cycle) of M symbols is         referred to (defined as) a “symbol group of period (cycle) M”.         The following description references FIG. 23.     -   When the number of consecutive symbols is at least M+1, a         plurality of a “symbol group of period (cycle) M” is arranged.         This point is described with reference to FIG. 24.

FIG. 23 illustrates examples of symbol groups when a “symbol group of period (cycle) M=5”. Features of FIG. 23 satisfy the following two points.

-   -   In a “symbol group of period (cycle) M=5”, the number of         (8,8)16APSK symbols is one greater than the number of         (12,4)16APSK symbols, in other words the number of (12,4)16APSK         symbols is two and the number of (8,8)16APSK symbols is three.     -   In a “symbol group of period (cycle) M=5”, there are no         consecutive (8,8)16APSK symbols or there is only 1 position at         which two consecutive (8,8)16APSK symbols exist. Accordingly,         there are no cases of three or more consecutive (8,8)16APSK         symbols.

Cases that satisfy the above two points, as methods of configuring a “symbol group of period (cycle) M=5”, are illustrated in parts (a), (b), (c), (d), and (e) of FIG. 23. In FIG. 23, the horizontal axis is time.

According to FIG. 23, part (a), when configuring a “symbol group of period (cycle) M=5”, a “symbol group of period (cycle) M=5” is an arrangement of symbols in the order (8,8)16APSK symbol, (12,4)16APSK symbol, (8,8)16APSK symbol, (12,4)16APSK symbol, and (8,8)16APSK symbol. Thus, a “symbol group of period (cycle) M=5” configured in this way is arranged in a repeating pattern.

According to FIG. 23, part (b), when configuring a “symbol group of period (cycle) M=5”, a “symbol group of period (cycle) M=5” is an arrangement of symbols in the order (12,4)16APSK symbol, (8,8)16APSK symbol, (12,4)16APSK symbol, (8,8)16APSK symbol, and (8,8)16APSK symbol. Thus, a “symbol group of period (cycle) M=5” configured in this way is arranged in a repeating pattern.

According to FIG. 23, part (c), when configuring a “symbol group of period (cycle) M=5”, a “symbol group of period (cycle) M=5” is an arrangement of symbols in the order (8,8)16APSK symbol, (12,4)16APSK symbol, (8,8)16APSK symbol, (8,8)16APSK symbol, and (12,4)16APSK symbol. Thus, a “symbol group of period (cycle) M=5” configured in this way is arranged in a repeating pattern.

According to FIG. 23, part (d), when configuring a “symbol group of period (cycle) M=5”, a “symbol group of period (cycle) M=5” is an arrangement of symbols in the order (12,4)16APSK symbol, (8,8)16APSK symbol, (8,8)16APSK symbol, (12,4)16APSK symbol, and (8,8)16APSK symbol. Thus, a “symbol group of period (cycle) M=5” configured in this way is arranged in a repeating pattern.

According to FIG. 23, part (e), when configuring a “symbol group of period (cycle) M=5”, a “symbol group of period (cycle) M=5” is an arrangement of symbols in the order (8,8)16APSK symbol, (8,8)16APSK symbol, (12,4)16APSK symbol, (8,8)16APSK symbol, and (12,4)16APSK symbol. Thus, a “symbol group of period (cycle) M=5” configured in this way is arranged in a repeating pattern.

Note that methods of configuring a “symbol group of period (cycle) M=5” are described with reference to FIG. 23, but the period (cycle) M is not limited to a value of five, and the following configurations are possible.

-   -   In a “symbol group of period (cycle) M”, the number of         (8,8)16APSK symbols is one greater than the number of         (12,4)16APSK symbols, in other words the number of (12,4)16APSK         symbols is N and the number of (8,8)16APSK symbols is N+1. Note         that N is a natural number.     -   In a “symbol group of period (cycle) M”, there are no         consecutive (8,8)16APSK symbols or there is only 1 position at         which two consecutive (8,8)16APSK symbols exist. Accordingly,         there are no cases of three or more consecutive (8,8)16APSK         symbols.

Accordingly, the period (cycle) M of a “symbol group of period (cycle) M” is an odd number greater than or equal to three, but when considering an increase of PAPR when a modulation scheme is (12,4)16APSK a period (cycle) M of greater than or equal to five is suitable. However, even when a period (cycle) M is three, there is the advantage that PAPR is less than PAPR of (8,8)16APSK.

The above describes configurations according to a “symbol group of period (cycle) M”, but a periodic (cyclic) configuration need not be adopted when the following is true.

-   -   When each data symbol is either a (12,4)16APSK symbol or an         (8,8)16APSK symbol, three or more consecutive (8,8)16APSK         symbols are not present in a consecutive data symbol group.

When constellations, labelling, and ring ratios of (12,4)16APSK and (8,8)16APSK are as described above and the condition described above is satisfied, a similar effect can be obtained.

In a case as described above, two consecutive (8,8)16APSK symbols may occur, but an effect of a lower PAPR than PAPR of (8,8)16APSK is achieved and an effect of improving data reception quality according to (12,4)16APSK is achieved.

The following is a supplemental description, referencing FIG. 24, of a method of configuring consecutive symbols composed of (12,4)16APSK symbols and (8,8)16APSK symbols when other symbols are inserted.

In FIG. 24, part (a), 2400, 2409 indicate other symbol groups (here, a symbol group may indicate consecutive symbols and may indicate a single symbol). These other symbol groups may indicate a control symbol for transmission of a transmission method such as a modulation scheme, an error correction coding scheme, etc., pilot symbols or reference symbol for a receive apparatus to perform channel estimation, frequency synchronization, and time synchronization, or a data symbol modulated by a modulation scheme other than (12,4)16APSK or (8,8)16APSK. In other words, the other symbol groups are symbols for which a modulation scheme is a modulation scheme other than (12,4)16APSK or (8,8)16APSK.

In FIG. 24, part (a), 2401, 2404, 2407, and 2410 indicate a first symbol of a “symbol group of period (cycle) M” (in a “symbol group of period (cycle) f”, a first symbol of the period (cycle)). 2403, 2406, and 2412 indicate a last symbol of a “symbol group of period (cycle) M” (in a “symbol group of period (cycle) M”, a last symbol of the period (cycle)).

2402, 2405, 2408, and 2411 indicate a mid symbol group of a “symbol group of period (cycle) M” (in a “symbol group of period (cycle) M”, a symbol group excluding the first symbol and the last symbol).

FIG. 24, part (a), illustrates an example of symbol arrangement along a horizontal axis of time. In FIG. 24, part (a), a first symbol 2401 of a “symbol group of period (cycle) M” is arranged immediately after the “other symbol group” 2400. Subsequently, a mid symbol group 2402 of the “symbol group of period (cycle) M” and a last symbol 2403 of the “symbol group of period (cycle) M” are arranged. Accordingly, a “first symbol group of period (cycle) M” is arranged immediately after the “other symbol group” 2400.

A “second symbol group of period (cycle) M” is arranged immediately after the “first symbol group of period (cycle) M”, the “second symbol group of period (cycle) M” being composed of a first symbol 2404, a mid symbol group 2045, and a last symbol 2406.

A first symbol 2407 of a “symbol group of period (cycle) M” is arranged after the “second symbol group of period (cycle) M”, and a portion 2408 of a mid symbol group of the “symbol group of period (cycle) M” is arranged subsequently.

The “other symbol group” 2409 is arranged after the portion 2408 of the mid symbol group of the “symbol group of period (cycle) M”.

A feature illustrated in FIG. 24, part (a), is that a “symbol group of period (cycle) M” is arranged after the “other symbol group” 2409, the “symbol group of period (cycle) M” being composed of a first symbol 2410, a mid symbol group 2411, and a last symbol 2412.

FIG. 24, part (b), illustrates an example of symbol arrangement along a horizontal axis of time. In FIG. 24, part (b), the first symbol 2401 of a “symbol group of period (cycle) M” is arranged immediately after the “other symbol group” 2400. Subsequently, the mid symbol group 2402 of the “symbol group of period (cycle) M” and the last symbol 2403 of the “symbol group of period (cycle) M” are arranged. Accordingly, the “first symbol group of period (cycle) M” is arranged immediately after the “other symbol group” 2400.

The “second symbol group of period (cycle) M” is arranged immediately after the “first symbol group of period (cycle) M”, the “second symbol group of period (cycle) M” being composed of the first symbol 2404, the mid symbol group 2045, and the last symbol 2406.

The first symbol 2407 of the “symbol group of period (cycle) M” is arranged after the “second symbol group of period (cycle) M”, and a portion 2408 of the mid symbol group of the “symbol group of period (cycle) M” is arranged subsequently.

The “other symbol group” 2409 is arranged after the portion 2408 of the mid symbol group of the “symbol group of period (cycle) M”.

A feature illustrated in FIG. 24, part (b) is that a remaining portion 2408-2 of the mid symbol group of the “symbol group of period (cycle) M” is arranged after the “other symbol group” 2409, and a last symbol 2413 of the “symbol group of period (cycle) M” is arranged subsequent to the remaining portion 2408. Note that a “symbol group of period (cycle) M” is formed by the first symbol 2407, the portion 2408 of the mid symbol group, the remaining portion 2408-2 of the mid symbol group, and the last symbol 2413.

A “symbol group of period (cycle) M” is arranged after the last symbol 2413, the “symbol group of period (cycle) M” being composed of a first symbol 2414, a mid symbol group 2415, and a last symbol 2416.

In FIG. 24, each “symbol group of period (cycle) M” may have the same configuration as the “symbol group of period (cycle) M” described as an example with reference to FIG. 23, and may be configured so that “in a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols”.

When constellations, labelling, and ring ratios of (12,4)16APSK and (8,8)16APSK are as described above and the conditions described above are satisfied, a similar effect can be obtained.

According to the examples described so far, 16APSK is an example of a modulation scheme used in switching, but 32APSK and 64APSK may be implemented in the same way.

A method of configuring consecutive symbols is as described above:

-   -   A “symbol group of period (cycle) M” is configured from a symbol         of a first modulation scheme of a first constellation in an         in-phase (I)-quadrature-phase (Q) plane and a symbol of a second         modulation scheme of a second constellation in an in-phase         (I)-quadrature-phase (Q) plane. (However, the number of         constellation points in the in-phase (I)-quadrature-phase (Q)         plane of the first modulation scheme and the number of         constellation points in the in-phase (I)-quadrature-phase (Q)         plane of the second modulation scheme are equal.)     -   In a symbol group of at least three consecutive symbols (or at         least four consecutive symbols), among which a modulation scheme         for each symbol is the first modulation scheme or the second         modulation scheme, there are no consecutive first modulation         scheme symbols and there are no consecutive second modulation         scheme symbols. (However, the number of constellation points in         the in-phase (I)-quadrature-phase (Q) plane of the first         modulation scheme and the number of constellation points in the         in-phase (I)-quadrature-phase (Q) plane of the second modulation         scheme are equal.)

FIG. 25 illustrates constellations in an in-phase (I)-quadrature-phase (Q) plane of a scheme of types of 32APSK having 32 constellation points in an in-phase (I)-quadrature-phase (Q) plane, according to the method described above of configuring two types of symbol as consecutive symbols.

FIG. 25, part (a) illustrates a constellation in an in-phase (I)-quadrature-phase (Q) plane of (4,12,16)32APSK. With an origin thereof as a center, constellation points a=4 exist on a circle of radius R₁, constellation points b=12 exist on a circle of radius R₂, and constellation points c=16 exist on a circle of radius R₃. Accordingly (a,b,c)=(4,12,16) and is therefore referred to as (4,12,16)32APSK (note that R₁<R₂<R₃).

FIG. 25, part (b) illustrates a constellation in an in-phase (I)-quadrature-phase (Q) plane of (8,8,16)32APSK. With an origin thereof as a center, constellation points a=8 exist on a circle of radius R₁, constellation points b=8 exist on a circle of radius R₂, and constellation points c=16 exist on a circle of radius R₃. Accordingly (a,b,c)=(8,8,16) and is therefore referred to as (8,8,16)32APSK (note that R₁<R₂<R₃).

Thus, the method of configuring two types of symbol as consecutive symbols described above may be implemented by (4,12,16)32APSK in FIG. 25, part (a), and (8,8,16)32APSK in FIG. 25, part (b). In other words, in the method of configuring two types of symbol as consecutive symbols described above, the first modulation scheme and the second modulation scheme may be (4,12,16)32APSK and (8,8,16)32APSK, respectively.

Further, with an origin thereof as a center, constellation points a=16 may exist on a circle of radius R₁ and constellation points b=16 may exist on a circle of radius R₂, (a,b)=(16,16), thereby describing (16,16)32APSK (note that R₁<R₂).

Thus, the method of configuring two types of symbol as consecutive symbols described above may be implemented by (4,12,16)32APSK in FIG. 25, part (a), and (16,16)32APSK. In other words, in the method of configuring two types of symbol as consecutive symbols described above, the first modulation scheme and the second modulation scheme may be (4,12,16)32APSK and (16,16)32APSK, respectively.

In addition a γ scheme 32APSK may be considered that has a different constellation to (4,12,16)32APSK, (8,8,16)32APSK, and (16,16)32APSK. Thus, the method of configuring two types of symbol as consecutive symbols described above may be implemented by (4,12,16)32APSK in FIG. 25, part (a), and the γ scheme 32APSK. In other words, in the method of configuring two types of symbol as consecutive symbols described above, the first modulation scheme and the second modulation scheme may be (4,12,16)32APSK and the γ scheme 32APSK, respectively.

Note that a labelling method with respect to constellation in an in-phase (I)-quadrature-phase (Q) plane of (12,4)16APSK and a labelling method with respect to constellation in an in-phase (I)-quadrature-phase (Q) plane of (8,8)16APSK are described in the present embodiment, but a labelling method with respect to constellation in an in-phase (I)-quadrature-phase (Q) plane that is different from the present embodiment may be applied (there is a possibility of achieving an effect similar to the effect of the present embodiment).

(Embodiment 2)

<Example of Pilot Symbols>

In the present embodiment, configuration examples of pilot symbols in the transmission method described in embodiment 1 are described.

Note that the transmit apparatus in the present embodiment is identical to the transmit apparatus described in embodiment 1 and therefore description thereof is omitted here.

Interference occurs between code (between symbols) of a modulated signal, because of non-linearity of the power amplifier of the transmit apparatus. High data reception quality can be achieved by a receive apparatus by decreasing this intersymbol interference.

In the present example of pilot symbol configuration, a method is described of transmitting baseband signals as pilot symbols, in order to decrease intersymbol interference at a receive apparatus. When data symbols are configured so that “in a symbol group of at least three consecutive symbols (or at least four consecutive symbols), among which a modulation scheme for each symbol is (12,4)16APSK or (8,8)16APSK, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols”, a transmit apparatus generates and transmits, as pilot symbols, baseband signals corresponding to all constellation points of (12,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane (in other words, baseband signals corresponding to the 16 constellation points of four transmit bits [b₃b₂b₁b₀] from [0000] to [1111]) and baseband signals corresponding to all constellation points of (8,8)16APSK on an in-phase (I)-quadrature-phase (Q) plane (in other words, baseband signals corresponding to the 16 constellation points of four transmit bits [b₃b₂b₁b₀] from [0000] to [1111]).

Thus, the receive apparatus can estimate intersymbol interference for all constellation points on an in-phase (I)-quadrature-phase (Q) plane of (12,4)16APSK and all constellation points on an in-phase (I)-quadrature-phase (Q) plane of (8,8)16APSK, and therefore there is a high possibility of achieving high data reception quality.

In the example illustrated in FIG. 13, the following are transmitted as pilot symbols, in order:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b_(b0)]=[0100] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK; a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (8,8)16APSK; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK; and a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (8,8)16APSK.

The above feature means that:

<1> Symbols corresponding to all constellation points on an in-phase (I)-quadrature-phase (Q) plane of (12,4)16APSK, i.e., the following symbols, are transmitted:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK.

Symbols corresponding to all constellation points on an in-phase (I)-quadrature-phase (Q) plane of (8,8)16APSK, i.e., the following symbols, are transmitted:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (8, 8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (8, 8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b_(b0)]=[1101] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (8,8)16APSK; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (8,8)16APSK.

<2> In a symbol group composed of consecutive pilot symbols, there are no consecutive (12,4)16APSK symbols and there are no consecutive (8,8)16APSK symbols. According to <1>, a receive apparatus can estimate intersymbol interference with high precision, and can therefore achieve high data reception quality. Further, according to <2>, an effect is achieved of lowering PAPR.

Note that pilot symbols are not only symbols for estimating intersymbol interference, and a receive apparatus may use pilot symbols to perform estimation of a radio wave propagation environment (channel estimation) between the transmit apparatus and the receive apparatus, and may use pilot symbols to perform frequency offset estimation and time synchronization.

Operation of a receive apparatus is described with reference to FIG. 2.

In FIG. 2, 210 indicates a configuration of a receive apparatus. The de-mapper 214 of FIG. 2 performs de-mapping with respect to mapping of a modulation scheme used by the transmit apparatus, for example obtaining and outputting a log-likelihood ratio for each bit. At this time, although not illustrated in FIG. 2, estimation of intersymbol interference, estimation of a radio wave propagation environment (channel estimation) between the transmit apparatus and the receive apparatus, time synchronization between the transmit apparatus and the receive apparatus, and frequency offset estimation between the transmit apparatus and the received apparatus may be performed in order to precisely perform de-mapping.

Although not illustrated in FIG. 2, the receive apparatus includes an intersymbol interference estimator, a channel estimator, a time synchronizer, and a frequency offset estimator. These estimators extract from receive signals a portion of pilot symbols, for example, and respectively perform intersymbol interference estimation, estimation of a radio wave propagation environment (channel estimation) between the transmit apparatus and the receive apparatus, time synchronization between the transmit apparatus and the receive apparatus, and frequency offset estimation between the transmit apparatus and the receive apparatus. Subsequently, the de-mapper 214 of FIG. 2 inputs these estimation signals and, by performing de-mapping based on these estimation signals, performs, for example, calculation of a log-likelihood ratio.

Further, a transmission method of pilot symbols is not limited to the example illustrated in FIG. 13 as long as the transmission method satisfies both <1> and <2> described above. For example, a modulation scheme of the 1st symbol of FIG. 13 may be (8,8)16APSK, and a transmission order of [b₃b₂b₁b₀] may be any transmission order. Further, the number of pilot symbols is not limited to 32 symbols as long as the pilot symbols satisfy both <1> and <2>. Accordingly, when composed of 32×N (N being a natural number) symbols, there is an advantage that the number of occurrences of each of the following symbols can be equalized:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (8, 8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (8, 8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (8, 8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (8,8)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (8,8)16APSK; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (8,8)16APSK.

(Embodiment 3)

<Signaling>

In the present embodiment, examples are described of various information signaled as TMCC information in order to facilitate reception at the receive apparatus of a transmit signal used in the transmission scheme described in embodiment 1 and embodiment 2.

Note that the transmit apparatus in the present embodiment is identical to the transmit apparatus described in embodiment 1 and therefore description thereof is omitted here.

FIG. 18 illustrates a schematic of a frame of a transmit signal of advanced wide band digital satellite broadcasting. (However, FIG. 18 is not intended to be an exact illustration of a frame of advanced wide band digital satellite broadcasting).

FIG. 18, part (a) indicates a frame along a horizontal axis of time, along which a “#1 symbol group”, a “#2 symbol group”, a “#3 symbol group”, . . . are arranged. Each symbol group of the “#1 symbol group”, the “#2 symbol group”, the “#3 symbol group”, . . . is composed of a “synchronization symbol group”, a “pilot symbol group”, a “TMCC information symbol group”, and “slots composed of a data symbol group”, as illustrated in FIG. 18, part (a). A “synchronization symbol group” is, for example, a symbol for a receive apparatus to perform time synchronization and frequency synchronization, and a “pilot symbol group” is used by a receive apparatus for processing as described above.

“Slots composed of a data symbol group” is composed of data symbols. Transmission methods used to generate data symbols, including error correction code, coding rate, code length, modulation scheme, etc., are switchable. Information related to transmission methods used to generate data symbols, including error correction code, coding rate, code length, modulation scheme, etc., is transmitted to a receive apparatus via a “TMCC information symbol group”.

FIG. 18, part (b), illustrates an example of a “TMCC information symbol group”. The following describes in particular a configuration of “transmission mode/slot information” of a “TMCC information symbol group”.

FIG. 18, part (c), illustrates a configuration of “transmission mode/slot information” of a “TMCC information symbol group”. In FIG. 18, part (c), “transmission mode 1” to “transmission mode 8” are illustrated, and “slots composed of data symbol group of #1 symbol group”, “slots composed of data symbol group of #2 symbol group”, “slots composed of data symbol group of #3 symbol group”, . . . each belong to a respective one of “transmission mode 1” to “transmission mode 8”.

Thus, modulation scheme information for generating symbols of “slots composed of a data symbol group” is transmitted by symbols for transmitting each modulation scheme of a transmission mode in FIG. 18, part (c) (indicated in FIG. 18, part (c), by “modulation scheme of transmission mode 1”, . . . , “modulation scheme of transmission mode 8”).

Further, coding rate information of error correction code for generating symbols of “slots composed of a data symbol group” is transmitted by symbols for transmitting each coding rate of a transmission mode in FIG. 18, part (c) (indicated in FIG. 18, part (c), by “coding rate of transmission mode 1”, . . . , “coding rate of transmission mode 8”).

Table 1 illustrates a configuration of modulation scheme information. In Table 1, for example, when four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0001], a modulation scheme for generating symbols of “slots composed of a symbol group” is π/2 shift binary phase shift keying (BPSK).

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0010], a modulation scheme for generating symbols of “slots composed of a symbol group” is quadrature phase shift keying (QPSK).

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of a “transmission mode/slot information” of a “TMCC information symbol group” are [0011], a modulation scheme for generating symbols of “slots composed of a symbol group” is 8 phase shift keying (8PSK).

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0100], a modulation scheme for generating symbols of “slots composed of a symbol group” is (12,4)16APSK.

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0101], a modulation scheme for generating symbols of “slots composed of a symbol group” is (8,8)16APSK.

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0110], a modulation scheme for generating symbols of “slots composed of a symbol group” is 32 amplitude phase shift keying (32APSK).

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0111], a modulation scheme for generating symbols of “slots composed of a symbol group” is a “transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols” (this may be the transmission method described in embodiment 1, for example, but the present description also describes other transmission methods (for example, embodiment 4)).

. . .

TABLE 1 Modulation scheme information Value Assignment 0000 Reserved 0001 π/2 shift BPSK 0010 QPSK 0011 8PSK 0100 (12,4)16APSK 0101 (8,8)16APSK 0110 32APSK 0111 Transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols . . . . . . 1111 No scheme assigned

Table 2 illustrates a relationship between coding rates of error correction code and ring ratios when a modulation scheme is (12,4)16APSK. According to R₁ and R₂, used above to represent constellation points in an I-Q plane of (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is represented as R_((12,4))=R₂/R₁.

In Table 2, for example, when four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0000], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 41/120 (≈1/3), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is 3.09.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0001], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 49/120 (≈2/5), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is 2.97.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0010], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 61/120 (≈1/2), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is 3.93.

. . .

TABLE 2 Relationship between coding rates of error correction code and ring ratios when modulation scheme is (12,4)16APSK Value Coding rate (approximate value) Ring ratio 0000 41/120 (1/3) 3.09 0001 49/120 (2/5) 2.97 0010 61/120 (1/2) 3.93 . . . . . . . . . 1111 No scheme assigned —

Table 3 illustrates a relationship between coding rates of error correction code and ring ratios when a modulation scheme is (8,8)16APSK. As above, according to R₁ and R₂ used in representing the constellation points in the I-Q plane of (8,8)16APSK, a ring ratio R_((8,8)) of (8,8)16APSK is represented as R_((8,8))=R₂/R₁. In Table 3, for example, when four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0000], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 41/120 (≈1/3), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (8,8)16APSK, a ring ratio R_((8,8)) of (8,8)16APSK is 2.70.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0001], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 49/120 (≈2/5), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (8,8)16APSK, a ring ratio R_((8,8)) of (8,8)16APSK is 2.60.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0010], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 61/120 (≈1/2), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (8,8)16APSK, a ring ratio R_((8,8)) of (8,8)16APSK is 2.50.

. . .

TABLE 3 Relationship between coding rates of error correction code and ring ratios when a modulation scheme is (8,8)16APSK Value Coding rate (approximate value) Ring ratio 0000 41/120 (1/3) 2.70 0001 49/120 (2/5) 2.60 0010 61/120 (1/2) 2.50 . . . . . . . . . 1111 No scheme assigned —

Table 4 illustrates a relationship between coding rates of error correction code and ring ratios when a transmission method mixes (12,4)16APSK symbols and (8,8)16APSK symbols.

In Table 4, for example, when four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0000], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 41/120 (≈1/3), and this means that when symbols for transmitting a modulation scheme of a transmission mode are indicated to be generated by a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols, a ring ratio R_((12,4)) of (12,4)16APSK is 4.20 and a ring ratio R_((8,8)) of (8,8)16APSK is 2.70.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0001], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 49/120 (≈2/5), and this means that when symbols for transmitting a modulation scheme of a transmission mode are indicated to be generated by a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols, a ring ratio R_((12,4)) of (12,4)16APSK is 4.10 and a ring ratio R_((8,8)) of (8,8)16APSK is 2.60.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0010], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 61/120 (≈1/2), and this means that when symbols for transmitting a modulation scheme of a transmission mode are indicated to be generated by a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols, a ring ratio R_((12,4)) of (12,4)16APSK is 4.00 and a ring ratio R_((8,8)) of (8,8)16APSK is 2.50.

. . .

TABLE 4 Relationship between coding rates of error correction code and ring ratios when transmission method mixes (12,4)16APSK symbols and (8,8)16APSK symbols. Coding rate (12,4)16APSK (8,8)16APSK Value (approximate value) ring ratio ring ratio 0000 41/120 (1/3) 4.20 2.70 0001 49/120 (2/5) 4.10 2.60 0010 61/120 (1/2) 4.00 2.50 . . . — . . . . . . 1111 No scheme assigned — —

Further, as in FIG. 22, the following transmission is performed by “stream type/relative stream information” of a “TMCC information symbol group”.

FIG. 22, part (a) illustrates a configuration of “stream type/relative stream information”. In FIG. 22, part (a), a configuration for transmitting stream type information is illustrated as an example including stream 0 to stream 15. In FIG. 22, part (a), “stream type of relative stream 0” indicates stream type information of stream 0.

Likewise, “stream type of relative stream 1” indicates stream type information of stream 1.

“Stream type of relative stream 2” indicates stream type information of stream 2.

. . .

“Stream type of relative stream 15” indicates stream type information of stream 15.

Stream type information for a stream is assumed to be composed of eight bits (however, this is just an example).

FIG. 22, part (b), illustrates examples of assignments to eight bit stream type information.

Eight bit stream type information [00000000] is reserved.

Eight bit stream type information [00000001] indicates that the stream is Moving Picture Experts Group-2 transport stream (MPEG-2TS).

Eight bit stream type information [00000010] indicates that the stream is type-length-value (TLV).

Eight bit stream type information [00000011] indicates that the stream is video (moving image) of resolution approximately 4 k (for example, 3840) pixels horizontally by approximately 2 k (for example 2160) pixels vertically. Video coding information may also be included.

Eight bit stream type information [00000100] indicates that the stream is video (moving image) of resolution approximately 8 k (for example, 7680) pixels horizontally by approximately 4 k (for example 4320) pixels vertically. Video coding information may also be included.

Eight bit stream type information [00000101] indicates that the stream is differential information for generating video (moving image) of resolution approximately 8 k (for example, 7680) pixels horizontally by approximately 4 k (for example 4320) pixels vertically from a video (moving image) of resolution approximately 4 k (for example, 3840) pixels horizontally by approximately 2 k (for example 2160) pixels vertically. Video coding information may also be included. This information is described further later.

. . .

Eight bit stream type information [11111111] is not assigned a type.

The following describes how eight bit stream type information [00000101] is used.

Assume the transmit apparatus transmits a stream of a video #A, which is a video (moving image) of resolution approximately 4 k (for example 3840) pixels horizontally by approximately 2 k (for example 2160) pixels vertically. Thus, the transmit apparatus transmits eight bit stream type information [00000011].

In addition, the transmit apparatus is assumed to transmit differential information for generating video (moving image) of resolution approximately 8 k (for example, 7680) pixels horizontally by approximately 4 k (for example 4320) pixels vertically from a video (moving image) of resolution approximately 4 k (for example, 3840) pixels horizontally by approximately 2 k (for example 2160) pixels vertically. Thus, the transmit apparatus transmits eight bit stream type information [00000101].

A receive apparatus receives the stream type information [00000011], determines from this information that the stream is a video (moving image) of resolution approximately 4 k (for example, 3840) pixels horizontally by approximately 2 k (for example 2160) pixels vertically, and can receive the video #A that is a video (moving image) of resolution approximately 4 k (for example, 3840) pixels horizontally by approximately 2 k (for example 2160) pixels vertically.

Further, in addition to the receive apparatus receiving the stream type information [00000011], and determining from this information that the stream is a video (moving image) of resolution approximately 4 k (for example, 3840) pixels horizontally by approximately 2 k (for example 2160) pixels vertically, the receive apparatus receives the stream type information [00000101] and determines from this information that the stream is differential information for generating a video (moving image) of resolution approximately 8 k (for example, 7680) pixels horizontally by approximately 4 k (for example 4320) pixels vertically from a video (moving image) of resolution approximately 4 k (for example, 3840) pixels horizontally by approximately 2 k (for example 2160) pixels vertically. Thus, the receive apparatus can obtain a video (moving image) of resolution approximately 8 k (for example, 7680) pixels horizontally by approximately 4 k (for example 4320) pixels vertically of the video #A from both streams.

Note that in order to transmit these streams, the transmit apparatus uses, for example, a transmission method described in embodiment 1 and embodiment 2. Further, as described in embodiment 1 and embodiment 2, when the transmit apparatus transmits these streams using modulation scheme of both (12,4)16APSK and (8,8)16APSK, the effects described in embodiment 1 and embodiment 2 can be achieved.

<Receive Apparatus>

The following describes operation of a receive apparatus that receives a radio signal transmitted by the transmit apparatus 700, with reference to the diagram of a receive apparatus in FIG. 19.

A receive apparatus 1900 of FIG. 19 receives a radio signal transmitted by the transmit apparatus 700 via an antenna 1901. An RF receiver 1902 performs processing such as frequency conversion and quadrature demodulation on a received radio signal, and outputs a baseband signal.

A demodulator 1904 performs processing such as root roll-off filter processing, and outputs a post-filter baseband signal.

A synchronization and channel estimator 1914 receives a post-filter baseband signal as input, performs time synchronization, frequency synchronization, and channel estimation, using, for example, a “synchronization symbol group” and “pilot symbol group” transmitted by the transmit apparatus, and outputs an estimated signal.

A control information estimator 1916 receives a post-filter baseband signal as input, extracts symbols including control information such as a “TMCC information symbol group”, performs demodulation and decoding, and outputs a control signal. Of importance in the present embodiment is that a receive apparatus demodulates and decodes a symbol transmitting “transmission mode modulation scheme” information and a symbol transmitting “transmission mode coding rate” of “transmission mode/slot information” of a “TMCC information symbol group”; and, based on Table 1, Table 2, Table 3, and Table 4, the control information estimator 1916 generates modulation scheme (or transmission method) information and error correction code scheme (for example, coding rate of error correction code) information used by “slots composed of a data symbol group”, and generates ring ratio information when a modulation scheme (or transmission method) used by “slots composed of a data symbol group” is a transmission method mixing (12,4)16APSK, (8,8)16APSK, 32APSK, (12,4)16APSK symbols and (8,8)16APSK symbols, and outputs the information as a portion of a control signal.

A de-mapper 1906 receives a post-filter baseband signal, control signal, and estimated signal as input, determines a modulation scheme (or transmission method) used by “slots composed of a data symbol group” based on the control signal (in this case, when there is a ring ratio, determination with respect to the ring ratio is also performed), calculates, based on this determination, a log-likelihood ratio (LLR) for each bit included in a data symbol from the post-filter baseband signal and estimated signal, and outputs the log-likelihood ratios. (However, instead of a soft decision value such as an LLR a hard decision value may be outputted, and a soft decision value instead of an LLR may be outputted.)

A de-interleaver 1908 receives log-likelihood ratios as input, accumulates input, performs de-interleaving (permutes data) corresponding to interleaving used by the transmit apparatus, and outputs post-de-interleaving log-likelihood ratios.

An error correction decoder 1912 receives post-de-interleaving log-likelihood ratios and a control signal as input, determines error correction coding used (code length, coding rate, etc.), performs error correction decoding based on this determination, and obtains estimated information bits. When the error correction code being used is an LDPC code, belief propagation (BP) decoding methods such as sum-product decoding, shuffled belief propagation (BP) decoding, and layered BP decoding may be used as a decoding method.

The above describes operation when iterative detection is not performed. The following is supplemental description of operation when iterative detection is performed. Note that a receive apparatus need not implement iterative detection, and a receive apparatus may be a receive apparatus that performs initial detection and error detection decoding without being provided with elements related to iterative detection that are described below.

When iterative detection is performed, the error correction decoder 1912 outputs a log-likelihood ratio for each post-decoding bit (note that when only initial detection is performed, output of a log-likelihood ratio for each post decoding bit is not necessary).

An interleaver 1910 interleaves a log-likelihood ratio for each post-decoding bit (performs permutation), and outputs a post-interleaving log-likelihood ratio.

The de-mapper 1906 performs iterative detection by using post-interleaving log-likelihood ratios, a post-filter baseband signal, and an estimated signal, and outputs a log-likelihood ratio for each post-iterative detection bit.

Subsequently, interleaving and error correction code operations are performed. Thus, these operations are iteratively performed. In this way, finally the possibility of achieving a preferable decoding result is increased.

In the above description, a feature thereof is that by a reception apparatus obtaining a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” and a symbol for transmitting coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group”; a modulation scheme, coding rate of error detection coding, and, when a modulation scheme is 16APSK, 32APSK, or a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols, ring ratios, are estimated and demodulation and decoding operations become possible.

The above description describes the frame configuration in FIG. 18, but frame configurations applicable to the present invention are not limited in this way. When a plurality of data symbols exist, a symbol for transmitting information related to a modulation scheme used in generating the plurality of data symbols, and a symbol for transmitting information related to an error correction scheme (for example, error correction code, code length of error correction code, coding rate of error correction code, etc.) exist, any arrangement in a frame may be used with respect to the plurality of data symbols, the symbol for transmitting information related to a modulation scheme, and the symbol for transmitting information related to an error correction scheme. Further, symbols other than these symbols, for example symbols for preamble and synchronization, pilot symbols, reference symbols, etc., may exist in a frame.

In addition, as a method different to that described above, a symbol transmitting information related to ring ratios may exist, and the transmit apparatus may transmit the symbol. An example of a symbol transmitting information related to ring ratios is illustrated below.

TABLE 5 Example of symbol transmitting information related to ring ratios Value Assignment 00000 (12,4)16APSK ring ratio 4.00 00001 (12,4)16APSK ring ratio 4.10 00010 (12,4)16APSK ring ratio 4.20 00011 (12,4)16APSK ring ratio 4.30 00100 (8,8)16APSK ring ratio 2.50 00101 (8,8)16APSK ring ratio 2.60 00110 (8,8)16APSK ring ratio 2.70 00111 (8,8)16APSK ring ratio 2.80 01000 (12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.50 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01001 (12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.60 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01010 (12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.70 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01011 (12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01100 (12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.50 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01101 (12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.60 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01110 (12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.70 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01111 (12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols . . . . . . 11111 . . .

According to Table 5, when [00000] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00”.

Further, the following is true.

When [00001] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10”.

When [00010] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.20”.

When [00011] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.30”.

When [00100] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(8,8)16APSK ring ratio 2.50”.

When [00101] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(8,8)16APSK ring ratio 2.60”.

When [00110] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(8,8)16APSK ring ratio 2.70”.

When [00111] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(8,8)16APSK ring ratio 2.80”.

When [01000] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.50 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01001] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.60 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01010] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.70 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01011] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01100] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.50 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01101] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.60 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01110] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.70 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01111] is transmitted by a symbol transmitting information related to a ring ratio, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

. . .

Thus, by obtaining a symbol transmitting information related to a ring ratio, a receive apparatus can estimate a ring ratio used by a data symbol, and therefore demodulation and decoding of the data symbol becomes possible.

Further, ring ratio information may be included in a symbol for transmitting a modulation scheme. An example is illustrated below.

TABLE 6 Modulation scheme information Value Assignment 00000 (12,4)16APSK ring ratio 4.00 00001 (12,4)16APSK ring ratio 4.10 00010 (12,4)16APSK ring ratio 4.20 00011 (12,4)16APSK ring ratio 4.30 00100 (8,8)16APSK ring ratio 2.50 00101 (8,8)16APSK ring ratio 2.60 00110 (8,8)16APSK ring ratio 2.70 00111 (8,8)16APSK ring ratio 2.80 01000 (12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.50 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01001 (12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.60 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01010 (12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.70 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01011 (12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01100 (12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.50 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01101 (12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.60 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01110 (12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.70 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols 01111 (12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols . . . . . . 11101 8PSK 11110 QPSK 11111 π/2 shift BPSK

According to Table 6, when [00000] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00”.

Further, the following is true.

When [00001] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10”.

When [00010] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.20”.

When [00011] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.30”.

When [00100] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(8,8)16APSK ring ratio 2.50”.

When [00101] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(8,8)16APSK ring ratio 2.60”.

When [00110] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(8,8)16APSK ring ratio 2.70”.

When [00111] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(8,8)16APSK ring ratio 2.80”.

When [01000] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.50 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01001] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.60 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01010] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.70 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01011] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01100] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.50 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01101] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.60 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01110] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.70 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

When [01111] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”.

. . .

When [11101] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “8PSK”.

When [11110] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “QPSK”.

When [11111] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “π/2 shift BPSK”.

Thus, by obtaining a symbol transmitting modulation scheme information, a receive apparatus can estimate a modulation scheme and ring ratio used by a data symbol, and therefore demodulation and decoding of the data symbol becomes possible.

Note that in the above description, examples are described including “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols”, “(12,4)16APSK”, and “(8,8)16APSK” as selectable modulation schemes (transmission methods), but modulation schemes (transmission methods) are not limited to these examples. For example, “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols” may be included as a selectable modulation scheme (transmission method); “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols” and “(12,4)16APSK” may be included as selectable modulation schemes (transmission methods); or “(12,4)16APSK ring ratio 4.10, (8,8)16APSK ring ratio 2.80 in a transmission method mixing (12,4)16APSK symbols and (8,8)16APSK symbols” and “(8,8)16APSK” may be included as selectable modulation schemes (transmission methods).

When a modulation scheme for which a ring ratio can be set is included among selectable modulation schemes, the transmit apparatus transmits information related to the ring ratio of the modulation scheme or a control symbol that enables estimation of the ring ratio, and therefore a receive apparatus can estimate a modulation scheme and ring ratio of a data symbol, and demodulation and decoding of the data symbol becomes possible.

(Embodiment 4)

In the present embodiment, an order of generation of a data symbol is described.

FIG. 18, part (a) illustrates a schematic of a frame configuration.

In FIG. 18, part (a), the “#1 symbol group”, the “#2 symbol group”, the “#3 symbol group”, . . . are lined up.

Each symbol group among the “#1 symbol group”, the “#2 symbol group”, the “#3 symbol group”, . . . is herein composed of a “synchronization symbol group”, a “pilot symbol group”, a “TMCC information symbol group”, and “slots composed of a data symbol group” as illustrated in FIG. 18, part (a).

Here, a configuration scheme is described of data symbol groups in each “slots composed of a data symbol group” among, for example, N symbol groups including the “#1 symbol group”, the “#2 symbol group”, the “#3 symbol group”, . . . , an “#N−1 symbol group”, an “#N symbol group”.

A rule is provided with respect to generation of data symbol groups in each “slots composed of a data symbol group” among N symbol groups from a “#(β×N+1) symbol group” to a “#(β×N+N) symbol group”. The rule is described with reference to FIG. 20.

In FIG. 20, “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” is written, but “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” means that the symbol group is generated, as described in embodiment 1, by a transmission method selected from:

-   -   “In a symbol group of at least three consecutive symbols (or at         least four consecutive symbols), among which a modulation scheme         for each symbol is (12,4)16APSK or (8,8)16APSK, there are no         consecutive (12,4)16APSK symbols and there are no consecutive         (8,8)16APSK symbols”; and     -   When each data symbol is either a (12,4)16APSK symbol or an         (8,8)16APSK symbol, three or more consecutive (8,8)16APSK         symbols are not present in a consecutive data symbol group, as         in the examples of FIG. 23.

Thus, “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” satisfies the features of FIG. 20, part (a) to part (f). Note that in FIG. 20, the horizontal axis is symbols.

FIG. 20, part (a):

When a 32APSK data symbol exists and an (8,8)16APSK data symbol does not exist, a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol exists after a “32APSK data symbol”, as illustrated in FIG. 20, part (a).

FIG. 20, part (b):

When an (8,8)16APSK data symbol exists, a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol exists after an “(8,8)16APSK data symbol”, as illustrated in FIG. 20, part (b).

FIG. 20, part (c):

When a (12,4)16APSK data symbol exists, a “(12,4)16APSK data symbol” exists after a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol, as illustrated in FIG. 20, part (c).

FIG. 20, part (d):

When an 8PSK data symbol exists and a (12,4)16APSK data symbol does not exist, an “8PSK data symbol” exists after a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol, as illustrated in FIG. 20, part (d).

FIG. 20, part (e):

When a QPSK data symbol exists, an 8PSK data symbol does not exist, and a (12,4)16APSK data symbol does not exist, a “QPSK data symbol” exists after a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol, as illustrated in FIG. 20, part (e).

FIG. 20, part (f):

When a π/2 shift BPSK data symbol exists, a QPSK data symbol does not exist, an 8PSK data symbol does not exist, and a (12,4)16APSK data symbol does not exist, a “π/2 shift BPSK data symbol” exists after a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol, as illustrated in FIG. 20, part (f).

When symbols are arranged as described above, there is an advantage that a receive apparatus can easily perform automatic gain control (AGC) because a signal sequence is arranged in order of modulation schemes (transmission methods) of high peak power.

FIG. 21 illustrates a method of configuring a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol, as described above.

Assume that a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol of a coding rate X of error correction code and a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol of a coding rate Y of error correction code exist. Also assume that a relationship X>Y is satisfied.

When the above is true, a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol of a coding rate Y of error correction code is arranged after a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol of a coding rate X of error correction code.

As in FIG. 21, assume that a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol of a coding rate 1/2 of error correction code, “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol of a coding rate 2/3 of error correction code, and a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol of a coding rate 3/4 of error correction code exist. Thus, from the above description, as illustrated in FIG. 21, symbols are arranged in the order of a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol of a coding rate 3/4 of error correction code, a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol of a coding rate 2/3 of error correction code, and a “(8,8)16APSK symbol and (12,4)16APSK symbol mixed” symbol of a coding rate 1/2 of error correction code.

(Embodiment 5)

According to embodiment 1 to embodiment 4, methods of switching (12,4)16APSK symbols and (8,8)16APSK symbols in a transmit frame, methods of configuring pilot symbols, methods of configuring control information including TMCC, etc., have been described.

Methods achieving a similar effect to embodiment 1 to embodiment 4 are not limited to methods using (12,4)16APSK symbols and (8,8)16APSK symbols in a transmit frame, and a method using (12,4)16APSK symbols and non-uniform (NU)-16QAM symbols can also achieve a similar effect to embodiment 1 to embodiment 4. In other words, NU-16QAM symbols may be used instead of (8,8)16APSK symbols in embodiment 1 to embodiment 4 (the modulation scheme used in combination is (12,4)16APSK). Accordingly, the present embodiment primarily describes using NU-16QAM symbols instead of (8,8)16APSK symbols.

<Constellation>

The following describes constellation and assignment of bits to each constellation point (labelling) of NU-16QAM performed by the mapper 708 of FIG. 7.

FIG. 26 illustrates an example of labelling a constellation of NU-16QAM in an in-phase (I)-quadrature-phase (Q) plane. In embodiment 1 to embodiment 4, description is provided using ring ratios, but here an “amplitude ratio” is defined instead of a ring ratio. When R₁ and R₂ are defined as in FIG. 26 (here, R₁ is a real number greater than zero and R₂ is a real number greater than zero, and R₁<R₂), an amplitude ratio A_(r)=R₂/R₁. Thus, an amplitude ratio of NU-16QAM is applicable instead of a ring ratio of (8,8)16APSK in embodiment 1 to embodiment 4.

Coordinates of each constellation point of NU-16QAM on the I-Q plane are as follows.

Constellation point 1-1 [0000] . . . (R₂,R₂)

Constellation point 1-2 [0001] . . . (R₂,R₁)

Constellation point 1-3 [0101] . . . (R₂,−R₁)

Constellation point 1-4 [0100] . . . (R₂,−R₂)

Constellation point 2-1 [0010] . . . (R₁,R₂)

Constellation point 2-2 [0011] . . . (R₁,R₁)

Constellation point 2-3 [0111] . . . (R₁,−R₁)

Constellation point 2-4 [0110] . . . (R₁,−R₂)

Constellation point 3-1 [1010] . . . (−R₁,R₂)

Constellation point 3-2 [1011] . . . (−R₁,R₁)

Constellation point 3-3 [1111] . . . (−R₁,−R₁)

Constellation point 3-4 [1110] . . . (−R₁,−R₂)

Constellation point 4-1 [1000] . . . (−R₂,R₂)

Constellation point 4-2 [1001] . . . (−R₂,R₁)

Constellation point 4-3 [1101] . . . (−R₂,−R₁)

Constellation point 4-4 [1100] . . . (−R₂,−R₂)

Further, for example, the following relationship is disclosed above:

Constellation point 1-1 [0000] . . . (R₂,R₂)

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[0000], an in-phase component I and quadrature component Q of a baseband signal after mapping are defined as (I,Q)=(R₂,R₂). As another example, the following relationship is disclosed above:

Constellation point 4-4 [1100] . . . (−R₂,−R₂)

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[1100], an in-phase component I and quadrature component Q of a baseband signal after mapping are defined as (I,Q)=(−R₂,−R₂).

This holds true for all of constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 3-1, constellation point 3-2, constellation point 3-3, constellation point 3-4, constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4.

<Transmission Output>

In order to achieve the same transmission output for (12,4)16APSK symbols and NU-16QAM symbols, the following normalization coefficient may be used. The normalization coefficient for (12,4)16APSK symbols is as described in embodiment 1. A normalization coefficient for NU-16QAM symbols is defined by the following formula.

$\begin{matrix} {\mspace{79mu}\left\lbrack {{Math}\mspace{14mu} 25} \right\rbrack} & \; \\ {a_{{NU} - {16\;{QAM}}} = \frac{z}{\sqrt{\left( {{4 \times 2 \times R_{1}^{2}} + {4 \times 2 \times R_{2}^{2}} + {8 \times \left( {R_{1}^{2} + R_{2}^{2}} \right)}} \right)/16}}} & \left( {{Math}\mspace{14mu} 25} \right) \end{matrix}$

Prior to normalization, the in-phase component of a baseband signal is I_(b) and the quadrature component of the baseband signal is Q_(b). After normalization, the in-phase component of the baseband signal is I_(n) and the quadrature component of the Baseband signal is Q_(n). Thus, when a modulation scheme is NU-16QAM, (I_(n), Q_(n))=(a_(NU-16QAM)×I_(b), a_(NU-16QAM)×Q_(b)) holds true.

When a modulation scheme is NU-16QAM, the in-phase component I_(b) and quadrature component Q_(b) are the in-phase component I and quadrature component Q, respectively, of a baseband signal after mapping that is obtained by mapping based on FIG. 26. Accordingly, when a modulation scheme is NU-16QAM, the following relationships hold true.

Constellation point 1-1 [0000] . . . (I_(n), Q_(n))=(a_(NU-16QAM)×R₂, a_(NU-16QAM)×R₂)

Constellation point 1-2 [0001] . . . (I_(n), Q_(n))=(a_(NU-16QAM)×R₂, a_(NU-16QAM)×R₁)

Constellation point 1-3 [0101] . . . (I_(n), Q_(n))=(a_(NU-16QAM)×R₂, −a_(NU-16QAM)×R₁)

Constellation point 1-4 [0100] . . . (I_(n), Q_(n))=(a_(NU-16QAM)×R₂, −a_(NU-16QAM)×R₂)

Constellation point 2-1 [0010] . . . (I_(n), Q_(n))=(a_(NU-16QAM)×R₁, a_(NU-16QAM)×R₂)

Constellation point 2-2 [0011] . . . (I_(n), Q_(n))=(a_(NU-16QAM)×R₁, a_(NU-16QAM)×R₁)

Constellation point 2-3 [0111] . . . (I_(n), Q_(n))=(a_(NU-16QAM)×R₁, −a_(NU-16QAM)×R₁)

Constellation point 2-4 [0110] . . . (I_(n), Q_(n))=(a_(NU-16QAM)×R₁, −a_(NU-16QAM)×R₂)

Constellation point 3-1 [1010] . . . (I_(n), Q_(n))=(−a_(NU-16QAM)×R₁, a_(NU-16QAM)×R₂)

Constellation point 3-2 [1011] . . . (I_(n), Q_(n))=(−a_(NU-16QAM)×R₁, a_(NU-16QAM)×R₁)

Constellation point 3-3 [1111] . . . (I_(n), Q_(n))=(−a_(NU-16QAM)×R₁, −a_(NU-16QAM)×R₁)

Constellation point 3-4 [1110] . . . (I_(n), Q_(n))=(−a_(NU-16QAM)×R₁, −a_(NU-16QAM)×R₂)

Constellation point 4-1 [1000] . . . (I_(n), Q_(n))=(−a_(NU-16QAM)×R₂, a_(NU-16QAM)×R₂)

Constellation point 4-2 [1001] . . . (I_(n), Q_(n))=(−a_(NU-16QAM)×R₂, a_(NU-16QAM)×R₁)

Constellation point 4-3 [1101] . . . (I_(n), Q_(n))=(−a_(NU-16QAM)×R₂, −a_(NU-16QAM)×R₁)

Constellation point 4-4 [1100] . . . (I_(n), Q_(n))=(−a_(NU-16QAM)×R₂, −a_(NU-16QAM)×R₂)

Further, for example, the following relationship is disclosed above:

Constellation point 1-1 [0000] . . . (I_(n), Q_(n))=(a_(NU-16QAM)×R₂, a_(NU-16QAM)×R₂)

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[0000], (I_(n), Q_(n))=(a_(NU-16QAM)×R₂, a_(NU-16QAM)×R₂). As another example, the following relationship is disclosed above:

Constellation point 4-4 [1100] . . . (I_(n), Q_(n))=(−a_(NU-16QAM)×R₂, −a_(NU-16QAM)×R₂)

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[1100], (I_(n), Q_(n))=(−a_(NU-16QAM)×R₂, −a_(NU-16QAM)×R₂).

This holds true for all of constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 3-1, constellation point 3-2, constellation point 3-3, constellation point 3-4, constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4.

Thus, the mapper 708 outputs I_(n) and Q_(n) as described above as an in-phase component and a quadrature component, respectively, of a baseband signal.

According to R₁ and R₂ used in representing the constellation points in the I-Q plane of (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK represents R_((12,4))=R₂/R₁.

When R₁ and R₂ are defined as in FIG. 26, an amplitude ratio of NU-16QAM is defined as A_(r)=R₂/R₁.

Thus, an effect is obtained that “when A_(r)<R_((12,4)), the probability of further lowering PAPR is high”.

This is because a modulation scheme likely to control peak power is NU-16QAM. Peak power generated by NU-16QAM is likely to increase as A_(r) increases. Accordingly, in order to avoid increasing peak power, setting A_(r) low is preferable. On the other hand, there is a high degree of freedom for R_((12,4)) of (12,4)16APSK as long as a value is set for which BER properties are good. Thus, it is likely that when A_(r)<R_((12,4)) a lower PAPR can be obtained.

However, even when A_(r)>R_((12,4)), an effect of lowering PAPR of NU-16QAM can be obtained. Accordingly, when focusing on improving BER properties, A_(r)>R_((12,4)) may be preferable.

<Labelling and Constellations of NU-16QAM>

[NU-16QAM Labelling]

Here, labelling of NU-16QAM is described. Labelling is the relationship between four bits [b₃b₂b₁b₀], which are input, and arrangement of constellation points in an in-phase (I)-quadrature-phase (Q) plane. FIG. 26 illustrates an example of NU-16QAM labelling, but as long as labelling satisfies <Condition 5> and <Condition 6>, below, labelling need not conform to FIG. 26.

For the purposes of description, the following definitions are used.

When four bits to be transmitted are [b_(a3)b_(a2)b_(a1)≠b_(a0)], a constellation point A is provided in the in-phase (I)-quadrature-phase (Q) plane, and when four bits to be transmitted are [b_(b3)b_(b2)b_(b1)b_(b0)], a constellation point B is provided in the in-phase (I)-quadrature-phase (Q) plane.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as zero.

Further, the following definitions are made.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as four.

Thus, group definitions are performed.

With respect to constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 3-1, constellation point 3-2, constellation point 3-3, constellation point 3-4, constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4 in the above description of NU-16QAM, constellation point 1-1, constellation point 1-2, constellation point 1-3, and constellation point 1-4 are defined as group 1. In the same way, constellation point 2-1, constellation point 2-2, constellation point 2-3, and constellation point 2-4 are defined as group 2; constellation point 3-1, constellation point 3-2, constellation point 3-3, and constellation point 3-4 are defined as group 3; and constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4 are defined as group 4.

The following two conditions are provided.

<Condition 5>

X represents 1, 2, 3, and 4. All values of X satisfy the following:

The number of different bits of labelling between constellation point X-1 and constellation point X-2 is one.

The number of different bits of labelling between constellation point X-2 and constellation point X-3 is one.

The number of different bits of labelling between constellation point X-3 and constellation point X-4 is one.

<Condition 6>

A value u represents 1, 2, and 3, and a value v represents 1, 2, 3, and 4. All values of u and all values of v satisfy the following:

The number of different bits of labelling between constellation point u−v and constellation point (u+1)−v is one.

By satisfying the above conditions, the number of different bits of labelling among constellation points that are near each other in an in-phase (I)-quadrature-phase (Q) plane is low, and therefore the possibility of a receive apparatus achieving high data reception quality is increased. Thus, when a receive apparatus performs iterative detection, the possibility of the receive apparatus achieving high data reception quality is increased.

When forming a symbol by NU-16QAM, as above, and (12,4)16APSK, and when implemented similarly to embodiment 1, any of the following transmission methods may be considered.

-   -   In a symbol group of at least three consecutive symbols (or at         least four consecutive symbols), among which a modulation scheme         for each symbol is (12,4)16APSK or NU-16QAM, there are no         consecutive (12,4)16APSK symbols and there are no consecutive         NU-16QAM symbols.     -   In a “symbol group of period (cycle) M”, the number of NU-16QAM         symbols is one greater than the number of (12,4)16APSK symbols,         in other words the number of (12,4)16APSK symbols is N and the         number of NU-16QAM symbols is N+1. Note that N is a natural         number. Thus, in a “symbol group of period (cycle) M”, there are         no consecutive NU-16QAM symbols or there is only 1 position at         which two consecutive NU-16QAM symbols exist. Accordingly, there         are no cases of three or more consecutive NU-16QAM symbols.     -   When each data symbol is either a (12,4)16APSK symbol or an         NU-16QAM symbol, three or more consecutive NU-16QAM symbols are         not present in a consecutive data symbol group.

Thus, by replacing description related to (8,8)16APSK symbols with NU-16QAM for portions of embodiment 1 to embodiment 4 in which (12,4)16APSK symbols and (8,8)16APSK symbols are described (for example, transmission method, pilot symbol configuration method, receive apparatus configuration, control information configuration including TMCC, etc.), a transmission method using (12,4)16APSK symbols and NU-16QAM can be implemented in the same way as described in embodiment 1 to embodiment 4.

(Embodiment 6)

In the present embodiment, an example is described of application to wide band digital satellite broadcasting of the transmission method, the transmit apparatus, the reception method, and the receive apparatus described in embodiment 1 to embodiment 5.

FIG. 27 illustrates a schematic of wide band digital satellite broadcasting. A satellite 2702 in FIG. 27 transmits a transmit signal by using the transmission method described in embodiment 1 to embodiment 5. This transmit signal is received by a terrestrial receive apparatus.

On the other hand, data for transmission by the satellite 2702 via a modulated signal is transmitted by a ground station 2701 in FIG. 27. Accordingly, the ground station 2701 transmits a modulation signal including data for transmission by a satellite. Thus, the satellite 2702 receives a modulated signal transmitted by the ground station 2701, and transmits data included in the modulated signal by using a transmission method described in embodiment 1 to embodiment 5.

(Embodiment 7)

In the present embodiment, description is provided of various information configuration examples signaled as TMCC information for smooth reception at a receive apparatus side performed by a transmit apparatus using a transmission method described in embodiment 1, embodiment 2, embodiment 5, etc.

In order to reduce distortion generated by a power amplifier included in the radio section 712 of the transmit apparatus in FIG. 7, there is a method of compensating for the distortion of the power amplifier or acquiring backoff information (difference value between operating point output of a modulated signal and saturation point output of a non-modulated signal).

In wide band digital satellite broadcasting, in relation to distortion of a power amplifier, “satellite output backoff” information is transmitted in TMCC information by a transmit apparatus.

In the present embodiment, a method of transmitting accurate information related to distortion of a power amplifier and a configuration of TMCC information are described. By transmission of the information described below, a receive apparatus can receive a modulated signal having little distortion, and therefore an effect can be achieved of improving data reception quality.

Transmission of “whether power amplifier performed distortion compensation” information and “index indicating degree of effect of distortion compensation of power amplifier” information as TMCC information is disclosed herein.

TABLE 7 Information related to distortion compensation of power amplifier Value Assignment 0 Distortion compensation of power amplifier OFF 1 Distortion compensation of power amplifier ON

Table 7 indicates a specific example of configuration of information related to distortion compensation of a power amplifier. As illustrated in FIG. 7, a transmit apparatus transmits “0”, when distortion compensation of a power amplifier is OFF, or “1”, when distortion compensation of a power amplifier is ON, as, for example, a portion of TMCC information (a portion of control information).

TABLE 8 Information related to index indicating degree of effect of distortion compensation of power amplifier Value Assignment 00 Between code (intersymbol) interference: High 01 Between code (intersymbol) interference: Medium 10 Between code (intersymbol) interference: Low 11 —

Table indicates a specific example of configuration of information related to an index indicating degrees of effect of distortion compensation of a power amplifier. When between code (intersymbol) interference is high, the transmit apparatus transmits “00”. When between code (intersymbol) interference is of a medium degree, the transmit apparatus transmits “01”. When between code (intersymbol) interference is low, the transmit apparatus transmits “10”.

In Table 2, Table 3, and Table 4 of embodiment 3, configurations are illustrated according to which a ring ratio is determined when a coding rate of error correction code is determined.

In the present embodiment, a different method is disclosed wherein a ring ratio is determined based on information related to distortion compensation of a power amplifier and/or information related to an index indicating a degree of effect of distortion compensation of a power amplifier and/or “satellite output backoff” information; and even when a coding rate of error correction code is set as A (even when a value is set), a transmit apparatus selects a ring ratio from among a plurality of candidates. As TMCC information, the transmit apparatus can notify a receive apparatus of modulation scheme information and ring ratio information by using the “modulation scheme information” of Table 1 and/or the “information related to ring ratio” of Table 5 and/or the “modulation scheme information” of Table 6.

FIG. 28 illustrates a block diagram related to ring ratio determination in connection with the above description. A ring ratio determiner 2801 of FIG. 28 receives “modulation scheme information”, “coding rate of error correction code information”, “satellite output backoff information”, “information related to distortion compensation of power amplifier (ON/OFF information)”, and an “index indicating degree of effect of distortion compensation of power amplifier” as input, uses all of this information or a portion of this information, determines a ring ratio when a modulation scheme (or transmission method) requires a ring ratio setting (for example, a transmission method using (8,8)16APSK, (12,4)16APSK, or a combination of (8,8)16APSK and (12,4)16APSK), and outputs ring ratio information that is determined. Subsequently, based on this ring ratio information, a mapper of the transmit apparatus performs mapping, and this ring ratio information is, for example, transmitted by the transmit apparatus to a receive apparatus as control information as in Table 5 and Table 6.

Note that a characteristic point of this embodiment is that when a modulation scheme A and coding rate B are selected, ring ratio can be set from a plurality of candidates.

For example, when a modulation scheme is (12,4)16APSK and a coding rate of error correction code is 61/129 (approximately 1/2), three types of ring ratio, C, D, and E, are candidates as a ring ratio. Thus, which value of ring ratio to use can be determined according to backoff status and information related to distortion compensation of a power amplifier (ON/OFF information). For example, when distortion compensation of a power amplifier is ON, a ring ratio may be selected that improves data reception quality of a receive apparatus, and when distortion compensation of a power amplifier is OFF and backoff is low, a ring ratio may be selected that decreases PAPR (ring ratio may be selected in similar ways for other coding rates, etc.). Note that this selection method can be applied in the same way when a modulation scheme is (8,8)16APSK, and when a transmission method is a transmission method combining (8,8)16APSK and (12,4)16APSK as described in embodiment 1.

According to the operations above, an effect is achieved of improving data reception quality of a receive apparatus and reducing load of a transmit power amplifier.

(Embodiment 8)

In embodiment 7 a case is described in which NU-16QAM symbols are used instead of (8,8)16APSK symbols in embodiment 1 to embodiment 4. In the present embodiment, (4,8,4)16APSK is disclosed as an extension of NU-16QAM (NU-16QAM is one example of (4.8.4)16APSK).

In the present embodiment, a case is described in which (4,8,4)16APSK symbols are used instead of (8,8)16APSK symbols in embodiment 1 to embodiment 4.

According to embodiment 1 to embodiment 4, methods of switching (12,4)16APSK symbols and (8,8)16APSK symbols in a transmit frame, methods of configuring pilot symbols, methods of configuring control information including TMCC, etc., have been described.

Methods achieving a similar effect to embodiment 1 to embodiment 4 are not limited to methods using (12,4)16APSK symbols and (8,8)16APSK symbols in a transmit frame, and a method using (12,4)16APSK symbols and (4,8,4)16APSK symbols can also achieve a similar effect to embodiment 1 to embodiment 4. In other words, (4,8,4)16APSK symbols may be used instead of (8,8)16APSK symbols in embodiment 1 to embodiment 4 (the modulation scheme used in combination is (12,4)16APSK).

Accordingly, the present embodiment primarily describes using (4,8,4)16APSK symbols instead of (8,8)16APSK symbols.

<Constellation>

As illustrated in FIG. 30, constellation points of (4,8,4)16APSK mapping are arranged on three concentric circles having different radii (amplitude components) in an in-phase (I)-quadrature-phase (Q) plane. In the present description, among these concentric circles, a circle having the largest radius R₃ is called an “outer circle”, a circle having an intermediate radius R₂ is called a “mid circle”, and a circle having the smallest radius R₁ is called an “inner circle”. When R₁, R₂, and R₃ are defined as in FIG. 30 (R₁ being a real number greater than zero, R₂ being a real number greater than zero, and R₃ being a real number greater than zero, R₁<R₂<R₃).

Further, four constellation points are arranged on the circumference of the outer circle, eight constellation points are arranged on the circumference of the mid circle, and four constellation points are arranged on the circumference of the inner circle. The (4,8,4) in (4,8,4)16APSK refers to the four, eight, four constellation points in the order of the outer circle, the mid circle, and the inner circle.

The following describes a constellation and assignment (labelling) of bits to each constellation point of (4,8,4)16APSK performed by the mapper 708 of FIG. 7.

FIG. 30 illustrates an example of labelling a constellation of (4,8,4)16APSK in an in-phase (I)-quadrature-phase (Q) plane. In embodiment 1 to embodiment 4, ring ratio is described, but in the case of (4,8,4)16APSK, two ring ratios are defined. A first ring ratio is r₁=R₂/R₁, and another ring ratio is r₂=R₃/R₁. Thus, two ring ratios of (4,8,4)16APSK, r₁=R₂/R₁ and r₂=R₃/R₁, are applicable instead of the ring ratio of (8,8)16APSK in embodiment 1 to embodiment 4.

Coordinates of each constellation point of (4,8,4)16APSK on the I-Q plane are as follows.

Constellation point 1-1 [0000] . . . (R₃ cos(π/4),R₃ sin(π/4))

Constellation point 1-2 [0001] . . . (R₂ cos λ,R₂×sin λ)

Constellation point 1-3 [0101] . . . (R₂ cos(−λ),R₂×sin(−λ))

Constellation point 1-4 [0100] . . . (R₃ cos(−π/4),R₃ sin(−π/4))

Constellation point 2-1 [0010] . . . (R₂ cos(−λ+π/2),R₂×sin(−λ+π/2))

Constellation point 2-2 [0011] . . . (R₁ cos(π/4),R₁ sin(π/4))

Constellation point 2-3 [0111] . . . (R₁ cos(−π/4),R₁ sin(−π/4))

Constellation point 2-4 [0110] . . . (R₂ cos(λ−π/2),R₂×sin(λ−π/2))

Constellation point 3-1 [1010] . . . (R₂ cos(λ+π/2),R₂×sin(λ+π/2))

Constellation point 3-2 [1011] . . . (R₁ cos(3π/4),R₁ sin(3π/4))

Constellation point 3-3 [1111] . . . (R₁ cos(−3π/4),R₁ sin(−3π/4))

Constellation point 3-4 [1110] . . . (R₂ cos(−λ−π/2),R₂×sin(−λ−π/2))

Constellation point 4-1 [1000] . . . (R₃ cos(3π/4),R₃ sin(3π/4))

Constellation point 4-2 [1001] . . . (R₂ cos(π−λ),R₂×sin(π−λ))

Constellation point 4-3 [1101] . . . (R₂ cos(−π+λ),R₂×sin(−π+λ))

Constellation point 4-4 [1100] . . . (R₃ cos(−3π/4),R₃ sin(−3π/4))

With respect to phase, the unit used is radians. Accordingly, for example, referring to R₃ cos(π/4), the unit of π/4 is radians. Hereinafter, the unit of phase is radians. Further, λ is greater than zero radians and smaller than π/4 (0 radians <λ<π/4 radians).

Further, for example, the following relationship is disclosed above:

Constellation point 1-1 [0000] . . . (R₃ cos(π/4),R₃ sin(π/4))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[0000], an in-phase component I and quadrature component Q of a baseband signal after mapping are defined as (I,Q)=(R₃ cos(π/4),R₃ sin(π/4)).

As another example, the following relationship is disclosed above:

Constellation point 4-4 [1100] . . . (R₃ cos(−3π/4),R₃ sin(−3π/4))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[1100], an in-phase component I and quadrature component Q of a baseband signal after mapping are defined as (I,Q)=(R₃ cos(−3π/4),R₃ sin(−3π/4)).

This holds true for all of constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 3-1, constellation point 3-2, constellation point 3-3, constellation point 3-4, constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4.

<Transmission Output>

In order to achieve the same transmission output for (12,4)16APSK symbols and (4,8,4)16APSK symbols, the following normalization coefficient may be used. The normalization coefficient for (12,4)16APSK symbols is as described in embodiment 1. The normalization coefficient for (4,8,4)16APSK symbols is defined by the following formula.

$\begin{matrix} \left\lbrack {{Math}\mspace{14mu} 26} \right\rbrack & \; \\ {{a\left( {4,8,4} \right)} = \frac{z}{\sqrt{\left( {{4 \times R_{1}^{2}} + {8 \times R_{2}^{2}} + {4 \times R_{3}^{2}}} \right)/16}}} & \left( {{Math}\mspace{14mu} 26} \right) \end{matrix}$

Prior to normalization, the in-phase component of a baseband signal is I_(b) and the quadrature component of the baseband signal is Q_(b). After normalization, the in-phase component of the baseband signal is I_(n) and the quadrature component of the baseband signal is Q_(n). Thus, when a modulation scheme is (4,8,4)16APSK, (I_(n), Q_(n))=(a_((4,8,4))×I_(b), a_((4,8,4))×Q_(b)) holds true.

When a modulation scheme is (4,8,4)16APSK, the in-phase component I_(b) and quadrature component Q_(b) are the in-phase component I and quadrature component Q, respectively, of a baseband signal after mapping that is obtained by mapping based on FIG. 30. Accordingly, when a modulation scheme is (4,8,4)16APSK, the following relationships hold true.

-   -   Constellation point 1-1 [0000] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₃ cos(π/4), a_((4,8,4))×R₃ sin(π/4))     -   Constellation point 1-2 [0001] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₂ cos λ, a_((4,8,4))×R₂×sin λ)     -   Constellation point 1-3 [0101] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₂ cos(−λ), a_((4,8,4)) R₂×sin(−λ))     -   Constellation point 1-4 [0100] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₃ cos(−π/4), a_((4,8,4))×R₃ sin(−π/4))     -   Constellation point 2-1 [0010] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₂ cos(−λ+π/2), a_((4,8,4))×R₂×sin(−λ+π/2))     -   Constellation point 2-2 [0011] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₁ cos(π/4), a_((4,8,4))×R₁ sin(π/4))     -   Constellation point 2-3 [0111] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₁ cos(−π/4), a_((4,8,4))×R₁ sin(−π/4))     -   Constellation point 2-4 [0110] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₂ cos(λ−π/2), a_((4,8,4))×R₂ sin(λ−π/2))     -   Constellation point 3-1 [1010] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₂ cos(λ+π/2), a_((4,8,4))×R₂×sin(λ+7π/2))     -   Constellation point 3-2 [1011] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₁ cos(3π/4), a_((4,8,4))×R₁ sin(3π/4))     -   Constellation point 3-3 [1111] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₁ cos(−3π/4), a_((4,8,4))×R₁ sin(−3π/4))     -   Constellation point 3-4 [1110] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₂ cos(−λ−π/2), a_((4,8,4))×R₂×sin(−λ−π/2))     -   Constellation point 4-1 [1000] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₃ cos(3π/4), a_((4,8,4))×R₃ sin(3π/4))     -   Constellation point 4-2 [1001] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₂ cos(π−λ), a_((4,8,4))×R₂ sin(π−λ))     -   Constellation point 4-3 [1101] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₂ cos(−π+λ), a_((4,8,4))×R₂×sin(−π+λ))     -   Constellation point 4-4 [1100] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₃ cos(−3π/4), a_((4,8,4))×R₃ sin(−3π/4))

Further, for example, the following relationship is disclosed above:

-   -   Constellation point 1-1 [0000] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₃ cos(π/4), a_((4,8,4))×R₃ sin(π/4))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[0000], (I_(n), Q_(n))=(a_((4,8,4))×R₃ cos(λ/4), a_((4,8,4))×R₃ sin(π/4)). As another example, the following relationship is disclosed above:

-   -   Constellation point 4-4 [1100] . . . (I_(n),         Q_(n))=(a_((4,8,4))×R₃ cos(−3π/4), a_((4,8,4))R₃ sin(−3π/4))

In data that is inputted to the mapper 708, this means that when four bits [b₃b₂b₁b₀]=[1100], (I_(n), Q_(n))=(a_((4,8,4))×R₃ cos(−3π/4), a_((4,8,4))×R₃ sin(−3π/4)).

This holds true for all of constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 3-1, constellation point 3-2, constellation point 3-3, constellation point 3-4, constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4.

Thus, the mapper 708 outputs I_(n) and Q_(n) as described above as an in-phase component and a quadrature component, respectively, of a baseband signal.

<Labelling and Constellations of (4,8,4)16APSK>

[Labelling of (4,8,4)16APSK]

The following describes labelling of (4,8,4)16APSK. Labelling is the relationship between four bits [b₃b₂b₁b₀], which are input, and arrangement of constellation points in an in-phase (I)-quadrature-phase (Q) plane. An example of labelling of (4,8,4)16APSK is illustrated in FIG. 30, but labelling need not conform to FIG. 30 as long as labelling satisfies the following <Condition 7> and <Condition 8>.

For the purposes of description, the following definitions are used.

When four bits to be transmitted are [b_(a3)b_(a2)b_(a1)b_(a0)], a constellation point A is provided in the in-phase (I)-quadrature-phase (Q) plane, and when four bits to be transmitted are [b_(b3)b_(b2)b_(b1)b_(b0)], a constellation point B is provided in the in-phase (I)-quadrature-phase (Q) plane.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as zero.

Further, the following definitions are made.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as one.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as two.

When b_(a3)=b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)=b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)=b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)=b_(b0), the number of different bits of labelling is defined as three.

When b_(a3)≠b_(b3), b_(a2)≠b_(b2), b_(a1)≠b_(b1), and b_(a0)≠b_(b0), the number of different bits of labelling is defined as four.

Thus, group definitions are performed. With respect to constellation point 1-1, constellation point 1-2, constellation point 1-3, constellation point 1-4, constellation point 2-1, constellation point 2-2, constellation point 2-3, constellation point 2-4, constellation point 3-1, constellation point 3-2, constellation point 3-3, constellation point 3-4, constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4 in the above description of (4,8,4)16APSK, constellation point 1-1, constellation point 1-2, constellation point 1-3, and constellation point 1-4 are defined as group 1.

In the same way, constellation point 2-1, constellation point 2-2, constellation point 2-3, and constellation point 2-4 are defined as group 2; constellation point 3-1, constellation point 3-2, constellation point 3-3, and constellation point 3-4 are defined as group 3; and constellation point 4-1, constellation point 4-2, constellation point 4-3, and constellation point 4-4 are defined as group 4.

The following two conditions are provided.

<Condition 7>

X represents 1, 2, 3, and 4. All values of X satisfy the following:

The number of different bits of labelling between constellation point X-1 and constellation point X-2 is one.

The number of different bits of labelling between constellation point X-2 and constellation point X-3 is one.

The number of different bits of labelling between constellation point X-3 and constellation point X-4 is one.

<Condition 8>

A value u represents 1, 2, and 3, and a value v represents 1, 2, 3, and 4. All values of u and all values of v satisfy the following:

The number of different bits of labelling between constellation point u−v and constellation point (u+1)−v is one.

By satisfying the above conditions, the number of different bits of labelling among constellation points that are near each other in an in-phase (I)-quadrature-phase (Q) plane is low, and therefore the possibility of a receive apparatus achieving high data reception quality is increased. Thus, when a receive apparatus performs iterative detection, the possibility of the receive apparatus achieving high data reception quality is increased.

[Constellation of (4,8,4)16APSK]

The above describes constellation and labelling in an in-phase (I)-quadrature-phase (Q) plane of FIG. 30, but constellation and labelling in an in-phase (I)-quadrature-phase (Q) plane is not limited to this example. For example, labelling of coordinates on an I-Q plane of each constellation point of (4,8,4)16APSK may be performed as follows.

Coordinates on an I-Q plane of the constellation point 1-1 [0000]: (cos θ×R₃×cos(π/4)−sin θ×R₃×sin(π/4), sin θ×R₃×cos(π/4)+cos θ×R₃×sin(π/4))

Coordinates on an I-Q plane of the constellation point 1-2 [0001]: (cos θ×R₂×cos λ−sin θ×R₂×sin λ, sin θ×R₂×cos λ+cos θ×R₂×sin λ)

Coordinates on an I-Q plane of the constellation point 1-3 [0101]: (cos θ×R₂×cos(−λ)−sin θ×R₂×sin(−λ), sin θ×R₂×cos(−λ)+cos θ×R₂×sin(−λ))

Coordinates on an I-Q plane of the constellation point 1-4 [0100]: (cos θ×R₃×cos(−π/4)−sin θ×R₃×sin(−π/4), sin θ×R₃×cos(−π/4)+cos θ×R₃×sin(−π/4))

Coordinates on an I-Q plane of the constellation point 2-1 [0010]: (cos θ×R₂×cos(−λ+π/2)−sin θ×R₂×sin(−λ+π/2), sin θ×R₂×cos(−λ+π/2)+cos θ×R₂×sin(−λ+π/2))

Coordinates on an I-Q plane of the constellation point 2-2 [0011]: (cos θ×R₁×cos(π/4)−sin θ×R₁×sin(π/4), sin θ×R₁×cos(π/4)+cos θ×R₁×sin(π/4))

Coordinates on an I-Q plane of the constellation point 2-3 [0111]: (cos θ×R₁×cos(−π/4)−sin θ×R₁×sin(−π/4), sin θ×R₁×cos(−π/4)+cos θ×R₁×sin(−π/4))

Coordinates on an I-Q plane of the constellation point 2-4 [0110]: (cos θ×R₂ cos(−π/2)−sin θ×R₂×sin(−π/2), sin θ×R₂×cos(λ−π/2)+cos θ×R₂×sin(−π/2))

Coordinates on an I-Q plane of the constellation point 3-1 [1010]: (cos θ×R₂ cos(λ+π/2)−sin θ×R₂×sin(+π/2), sin θ×R₂ cos(λ+π/2)+cos θ×R₂×sin(+π/2))

Coordinates on an I-Q plane of the constellation point 3-2 [1011]: (cos θ×R₁×cos(3π/4)−sin θ×R₁×sin(3π/4), sin θ×R₁×cos(3π/4)+cos θ×R₁×sin(3π/4))

Coordinates on an I-Q plane of the constellation point 3-3 [1111]: (cos θ×R₁×cos(−3π/4)−sin θ×R₁×sin(−3π/4), sin θ×R₁×cos(−3π/4)+cos θ×R₁×sin(−3π/4))

Coordinates on an I-Q plane of the constellation point 3-4 [1110]: (cos θ×R₂×cos(−λ−π/2)−sin θ×R₂×sin(−λ−π/2), sin θ×R₂×cos(−λ−π/2)+cos θ×R₂×sin(−λ−π/2))

Coordinates on an I-Q plane of the constellation point 4-1 [1000]: (cos θ×R₃×cos(3π/4)−sin θ×R₃×sin(3π/4), sin θ×R₃×cos(3π/4)+cos θ×R₃×sin(3π/4))

Coordinates on an I-Q plane of the constellation point 4-2 [1001]: (cos θ×R₂×cos(π−λ)−sin θ×R₂×sin(π−λ), sin θ×R₂×cos(π−λ)+cos θ×R₂×sin(π−λ))

Coordinates on an I-Q plane of the constellation point 4-3 [1101]: (cos θ×R₂×cos(−π+λ)−sin θ×R₂×sin(−π+λ), sin θ×R₂×cos(−π+λ)+cos θ×R₂×sin(−π+λ))

Coordinates on an I-Q plane of the constellation point 4-4 [1100]: (cos θ×R₃×cos(−3π/4)−sin θ×R₃×sin(−3π/4), sin θ×R₃×cos(−3π/4)+cos θ×R₃ sin(−3π/4))

With respect to phase, the unit used is radians. Accordingly, an in-phase component I_(n) and a quadrature component Q_(n) of a baseband signal after normalization is represented as below.

Coordinates on an I-Q plane of the constellation point 1-1 [0000]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₃×cos(π/4)−a_((4,8,4))×sin θ×R₃ sin(π/4), a_((4,8,4))×sin θ×R₃×cos(π/4)+a_((4,8,4))×cos θ×R₃×sin(π/4))

Coordinates on an I-Q plane of the constellation point 1-2 [0001]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₂×cos λ−a_((4,8,4))×sin θR₂×sin λ, a_((4,8,4)) sin θ×R₂×cos λ+a_((4,8,4))×cos R₂×sin λ)

Coordinates on an I-Q plane of the constellation point 1-3 [0101]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₂×cos(−λ)−a_((4,8,4))×sin θ×R₂×sin(−λ), a_((4,8,4))×sin θ×R₂×cos(−λ)+a_((4,8,4))×cos θ×R₂×sin(−λ))

Coordinates on an I-Q plane of the constellation point 1-4 [0100]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₃×cos(−π/4)−a_((4,8,4)) sin θ×R₃×sin(−π/4), a_((4,8,4))×sin θ×R₃×cos(−7π/4)+a_((4,8,4))×cos θ×R₃×sin(−π/4))

Coordinates on an I-Q plane of the constellation point 2-1 [0010]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₂×cos(−λ+π/2)−a_((4,8,4)) sin θ×R₂×sin(−λ+π/2), a_((4,8,4))×sin θ×R₂×cos(−λ+π/2)+a_((4,8,4))×cos θ×R₂×sin(−λ+π/2))

Coordinates on an I-Q plane of the constellation point 2-2 [0011]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₁×cos(π/4)−a_((4,8,4)) sin θ×R₁×sin(π/4), a_((4,8,4))×sin θ×R₁×cos(π/4)+a_((4,8,4))×cos θ×R₁×sin(π/4))

Coordinates on an I-Q plane of the constellation point 2-3 [0111]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₁×cos(−π/4)−a_((4,8,4)) sin θ×R₁×sin(−π/4), a_((4,8,4))×sin θ×R₁×cos(−π/4)+a_((4,8,4))×cos θ×R₁×sin(−π/4))

Coordinates on an I-Q plane of the constellation point 2-4 [0110]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₂×cos(λ−π/2)−a_((4,8,4))×sin θ×R₂×sin(λ−π/2), a_((4,8,4))×sin θ×R₂ cos(λ−π/2)+a_((4,8,4))×cos θ×R₂×sin(λ−π/2))

Coordinates on an I-Q plane of the constellation point 3-1 [1010]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₂×cos(λ+π/2)−a_((4,8,4))×sin θ×R₂×sin(λ+π/2), a_((4,8,4))×sin θ×R₂×cos(λ+π/2)+a_((4,8,4))×cos θ×R₂×sin(λ+π/2))

Coordinates on an I-Q plane of the constellation point 3-2 [1011]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₁×cos(3π/4)−a_((4,8,4))×sin θ×R₁×sin(3π/4), a_((4,8,4)) sin θ×R₁×cos(3π/4)+a_((4,8,4))×cos θ×R₁×sin(3π/4))

Coordinates on an I-Q plane of the constellation point 3-3 [1111]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₁×cos(−3π/4)−a_((4,8,4)) sin θ×R₁×sin(−3π/4), a_((4,8,4)) sin θ×R₁×cos(−3π/4)+a_((4,8,4))×cos θ×R₁×sin(−3π/4))

Coordinates on an I-Q plane of the constellation point 3-4 [1110]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₂×cos(−λ−7π/2)−a_((4,8,4)) sin θ×R₂×sin(−λ−π/2), a_((4,8,4))×sin θ×R₂×cos(−λ−π/2)+a_((4,8,4))×cos θ×R₂×sin(−λ−π/2))

Coordinates on an I-Q plane of the constellation point 4-1 [1000]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₃×cos(3π/4)−a_((4,8,4))×sin θ×R₃ sin(3π/4), a_((4,8,4))×sin θ×R₃×cos(3π/4)+a_((4,8,4))×cos θ×R₃ sin(3π/4))

Coordinates on an I-Q plane of the constellation point 4-2 [1001]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₂×cos(π−λ)−a_((4,8,4))×sin θ×R₂×sin(−λ), a_((4,8,4)) sin θ×R₂ cos(π−λ)+a_((4,8,4))×cos θ×R₂×sin(π−λ))

Coordinates on an I-Q plane of the constellation point 4-3 [1101]: (I_(n), Q_(n))=(a_((4,8,4))×cos θ×R₂×cos(−π+λ)−a_((4,8,4))×sin θ×R₂×sin(−π+λ), a_((4,8,4))×sin θ×R₂×cos(−π+λ)+a_((4,8,4))×cos θ×R₂×sin(−π+λ))

Coordinates on an I-Q plane of the constellation point 4-4 [1100]: (I_(n), Q_(n))=(a_((4,8,4))×cos R₃×cos(−3π/4)−a_((4,8,4)) sin θ×R₃ sin(−3π/4), a_((4,8,4))×sin θ×R₃×cos(−3π/4)+a_((4,8,4))×cos θ×R₃×sin(−3π/4))

Note that θ is a phase provided on an in-phase (I)-quadrature-phase (Q) plane, and a_((4,8,4)) is as shown in Math (26).

When forming a symbol by (4,8,4)16APSK, as above, and (12,4)16APSK, and when implemented similarly to embodiment 1, any of the following transmission methods may be considered.

-   -   In a symbol group of at least three consecutive symbols (or at         least four consecutive symbols), among which a modulation scheme         for each symbol is (12,4)16APSK or (4,8,4)16APSK, there are no         consecutive (12,4)16APSK symbols and there are no consecutive         (4,8,4)16APSK symbols”.     -   In a “symbol group of period (cycle) M”, the number of         (4,8,4)16APSK symbols is one greater than the number of         (12,4)16APSK symbols, in other words the number of (12,4)16APSK         symbols is N and the number of (4,8,4)16APSK symbols is N+1.         Note that N is a natural number. Thus, in a “symbol group of         period (cycle) M”, there are no consecutive (4,8,4)16APSK         symbols or there is only 1 position at which two consecutive         (4,8,4)16APSK symbols exist. Accordingly, three or more         consecutive (4,8,4)16APSK symbols do not exist.     -   When each data symbol is either a (12,4)16APSK symbol or a         (4,8,4)16APSK symbol, three or more consecutive (4,8,4)16APSK         symbols are not present in a consecutive data symbol group.

Thus, by replacing description related to (8,8)16APSK symbols with (4,8,4)16APSK for portions of embodiment 1 to embodiment 4 in which (12,4)16APSK symbols and (8,8)16APSK symbols are described (for example, transmission method, pilot symbol configuration method (embodiment 2), receive apparatus configuration, control information configuration including TMCC, etc.), a transmission method using (12,4)16APSK symbols and (4,8,4)16APSK can be implemented in the same way as described in embodiment 1 to embodiment 4.

(Embodiment 9)

In embodiment 8, a case is described in which (4,8,4)16APSK symbols are used instead of the (8,8)16APSK symbols in embodiment 1 to embodiment 4. In the present embodiment, conditions are described related to constellations for improving data reception quality with respect to the (4,8,4)16APSK described in embodiment 8.

As stated in embodiment 8, FIG. 30 illustrates an example arrangement of 16 constellation points of (4,8,4)16APSK in an in-phase (I)-quadrature-phase (Q) plane. Here, phases forming a half-line of Q=0 and I≥0 and a half-line of Q=(tan λ)×I and Q≥0 are considered to be λ (radians) (0 radians <λ<π/4 radians).

In FIG. 30, 16 constellation points of (4,8,4)16APSK are drawn so that λ<π/8 radians.

In FIG. 31, 16 constellation points of (4,8,4)16APSK are drawn so that λ≥π/8 radians.

First, eight constellation points, i.e. constellation point 1-2, constellation point 1-3, constellation point 2-1, constellation point 2-4, constellation point 3-1, constellation point 3-4, constellation point 4-2, and constellation point 4-3 exist on an intermediate size “mid circle” of radius R₂. Focusing on these eight constellation points, a method of setting λ to π/8 radians, as in a constellation of 8PSK, may be considered in order to achieve high reception quality.

However, four constellation points, i.e., constellation point 1-1, constellation point 1-4, constellation point 4-1, and constellation point 4-4 exist on a largest “outer circle” of radius R₃. Further, four constellation points, i.e., constellation point 2-2, constellation point 2-3, constellation point 3-2, and constellation point 3-3, exist on a smallest “inner circle” of radius R₁. When focusing on the relationship between these constellation points and the eight constellation points on the “mid circle”, <Condition 9> is preferably satisfied (Condition 9 becomes a condition for achieving high data reception quality).

<Condition 9>

λ<π/8 radians

This point is described with reference to FIG. 30 and FIG. 31. In FIG. 30 and FIG. 31, constellation point 1-2 and constellation point 2-1 on the “mid circle”, constellation point 1-1 on the “outer circle”, and constellation point 2-2 on the “inner circle”, all in a first quadrant, are focused on. Although constellation point 1-2, constellation point 2-1, constellation point 1-1, and constellation point 2-2 in the first quadrant are focused on, discussion focusing on these four constellation points also applies to four constellation points in a second quadrant, four constellation points in a third quadrant, and four constellation points in a fourth quadrant.

As can be seen from FIG. 31, when λ≥π/8, a distance between constellation point 1-2 and constellation point 2-1 on the “mid circle” and constellation point 1-1 on the “outer circle” becomes short. Thus, because resistance to noise is reduced, data reception quality by a receive apparatus decreases.

In the case of FIG. 31, constellation point 1-1 on the “outer circle” is focused on, but according to values of R₁, R₂, and R₃, focus on constellation point 2-2 on the “inner circle” may be required, so that when λ≥π/8 radians, a distance between constellation point 1-2 and constellation point 2-1 on the “mid circle” and constellation point 2-2 on the “inner circle” becomes short. Thus, because resistance to noise is reduced, data reception quality by a receive apparatus decreases.

On the other hand, when λ<π/8 radians is set as in FIG. 30, a distance between constellation point 1-1 and constellation point 1-2, a distance between constellation point 1-1 and constellation point 2-1, a distance between constellation point 2-2 and constellation point 1-2, and a distance between constellation point 2-2 and constellation point 2-1 can all be set larger, which is one condition for achieving high data reception quality.

From the above points, <Condition 9> becomes an important condition for a receive apparatus to achieve high data reception quality.

The following describes further conditions for a receive apparatus to achieve high data reception quality.

In FIG. 32, constellation point 1-2 and constellation point 2-2 of the first quadrant are focused on. Although constellation point 1-2 and constellation point 2-2 of the first quadrant are focused on here, this focus is also applicable to constellation point 3-2 and constellation point 4-2 of the second quadrant, constellation point 3-3 and constellation point 4-3 of the third quadrant, and constellation point 1-3 and constellation point 2-3 of the fourth quadrant.

Coordinates of constellation point 1-2 are (R₂ cos λ,R₂ sin λ), and coordinates of constellation point 2-2 are (R₁ cos(π/4),R₁ sin(π/4)). In order to increase the probability of a receive apparatus achieving a high data reception quality, the following condition is provided.

<Condition 10>

R₁ sin(π/4)<R₂ sin λ

Among the four constellation points on the “inner circle”, the smallest Euclidean distance is α. (Euclidean distance between constellation point 2-2 and constellation point 2-3, Euclidean distance between constellation point 2-3 and constellation point 3-3, and Euclidean distance between constellation point 3-2 and constellation point 2-2 is α.)

Among the eight constellation points on the “mid circle”, a Euclidean distance between constellation point 1-2 and constellation point 1-3 is β. Distance between constellation point 2-1 and constellation point 3-1, distance between constellation point 4-2 and constellation point 4-3, and distance between constellation point 3-4 and constellation point 2-4 is also β.

When <Condition 10> is satisfied, α<β holds true.

Considering the points above, when both <Condition 9> and <Condition 10> are satisfied, and when Euclidean distance derived by extracting two different constellation points among 16 constellation points is considered, regardless of which two constellation points are extracted, the Euclidean distance is large, and therefore the possibility of a receive apparatus achieving high data reception quality is increased.

However, there is the possibility of a receive apparatus achieving high data reception quality without satisfying <Condition 9> and/or <Condition 10>. This is because there is the possibility of different suitable conditions existing according to distortion characteristics (for example, see FIG. 1) of a power amplifier for transmission included in the radio section 712 of the transmit apparatus illustrated in FIG. 7.

In this case, when considering arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as disclosed in embodiment 8, the following condition is added in addition to <Condition 10>

Coordinates of constellation point 1-2 are (R₂ cos λ,R₂×sin λ), and coordinates of constellation point 2-2 are (R₁ cos(π/4),R₁ sin(π/4)). Thus, the following condition is provided.

<Condition 11>

R₁ sin(π/4)≠R₂×sin λ

Coordinates of constellation point 1-1 are (R₃ cos(π/4),R₃ sin(π/4)), and coordinates of constellation point 1-2 are (R₂ cos λ,R₂×sin λ). Thus, the following condition is provided.

<Condition 12>

R₂ cos λ≠R₃ cos(π/4)

Thus, the following nine (4,8,4)16APSK are considered.

[1] Satisfying <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[2] Satisfying <Condition 11> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[3] Satisfying <Condition 12> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[4] Satisfying <Condition 9> and <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[5] Satisfying <Condition 9> and <Condition 11> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[6] Satisfying <Condition 9> and <Condition 12> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[7] Satisfying <Condition 10> and λ=π/12 for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[8] Satisfying <Condition 11> and λ=π/12 for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[9] Satisfying <Condition 12> and λ=π/12 for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

Constellations (coordinates of constellation points) on an in-phase (I)-quadrature-phase (Q) plane of these nine (4,8,4)16APSK schemes are different from constellations (coordinates of constellation points) on an in-phase (I)-quadrature-phase (Q) plane of the NU-16QAM scheme described in embodiment 7, and are constellations characteristic of the present embodiment.

Further, the following nine (4,8,4)16APSK are considered.

[10] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[11] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 11> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[12] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 12> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[13] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 9> and <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[14] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 9> and <Condition 11> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[15] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 9> and <Condition 12> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[16] Satisfying <Condition 7> and <Condition 8>, λ=π/12 radians, and satisfying <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[17] Satisfying <Condition 7> and <Condition 8>, λ=π/12 radians, and satisfying <Condition 11> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[18] Satisfying <Condition 7>, and <Condition 8>, λ=π/12 radians, and satisfying <Condition 12> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

According to the above, the number of different bits of labelling among constellation points that are near each other in an in-phase (I)-quadrature-phase (Q) plane is low, and therefore the possibility of a receive apparatus achieving high data reception quality is increased. Thus, when a receive apparatus performs iterative detection, the possibility of the receive apparatus achieving high data reception quality is increased.

(Embodiment 10)

According to embodiment 1 to embodiment 4, methods of switching (12,4)16APSK symbols and (8,8)16APSK symbols in a transmit frame, methods of configuring pilot symbols, methods of configuring control information including TMCC, etc., have been described. Embodiment 7 describes a method using NU-16QAM instead of (8,8)16APSK as described in embodiment 1 to embodiment 4, and embodiment 8 describes a method using (4,8,4)16APSK instead of (8,8)16APSK as described in embodiment 1 to embodiment 4.

In embodiment 9, a constellation of (4,8,4)16APSK is described for a receive apparatus to achieve improved data reception quality in a method using (4,8,4)16APSK instead of the (8,8)16APSK described in embodiment 1 to embodiment 4.

For example, in a situation in which distortion characteristics are severe, such as satellite broadcasting by using a power amplifier for transmission included in the radio section 712 of the transmit apparatus illustrated in FIG. 7, even when (only) using (4,8,4)16APSK as a modulation scheme, PAPR is low and therefore intersymbol interference is reduced and, when compared to (12,4)16APSK, (4,8,4)16APSK improves constellation and labelling, and therefore a receive apparatus is likely to achieve high data reception quality.

In the present embodiment, this point, i.e., a transmission method that can specify (4,8,4)16APSK as a modulation scheme of data symbols is described.

For example, in a frame of a modulated signal such as in FIG. 11, (4,8,4)16APSK can be specified as a modulation scheme of Data #1 to Data #7920.

Accordingly, in FIG. 11, when “1st symbol, 2nd symbol, 3rd symbol, . . . , 135th symbol, 136th symbol” are arranged along a horizontal axis of time, (4,8,4)16APSK can be specified as the modulation scheme of “1st symbol, 2nd symbol, 3rd symbol, . . . , 135th symbol, 136th symbol”.

As one feature of such configuration, “two or more (4,8,4)16APSK symbols are consecutive”. Two or more consecutive (4,8,4)16APSK symbols are consecutive along a time axis when, for example, a single carrier transmission scheme is used (see FIG. 33). Further, when a multi-carrier transmission scheme such as orthogonal frequency division multiplexing (OFDM) is used, the two or more consecutive (4,8,4)16APSK symbols may be consecutive along a time axis (see FIG. 33), and may be consecutive along a frequency axis (see FIG. 34).

FIG. 33 illustrates an example arrangement of symbols when time is a horizontal axis. A (4,8,4)16APSK symbol at time #1, a (4,8,4)16APSK symbol at time #2, a (4,8,4)16APSK symbol at time #3, . . . .

FIG. 34 illustrates an example arrangement of symbols when frequency is a horizontal axis. A (4,8,4)16APSK symbol at carrier #1, a (4,8,4)16APSK symbol at carrier #2, a (4,8,4)16APSK symbol at carrier #3, . . . .

Further examples of “two or more (4,8,4)16APSK symbols are consecutive” are illustrated in FIG. 35 and FIG. 36.

FIG. 35 illustrates an example arrangement of symbols when time is a horizontal axis. Another symbol at time #1, a (4,8,4)16APSK symbol at time #2, a (4,8,4)16APSK symbol at time #3, a (4,8,4)16APSK symbol at time #4, another symbol at time #5, . . . . The other symbol may be a pilot symbol, a symbol transmitting control information, a reference symbol, a symbol for frequency or time synchronization, or any kind of symbol.

FIG. 36 illustrates an example arrangement of symbols when frequency is a horizontal axis. Another symbol at carrier #1, a (4,8,4)16APSK symbol at carrier #2, a (4,8,4)16APSK symbol at carrier #3, a (4,8,4)16APSK symbol at carrier #4, another symbol at carrier #5, . . . . The other symbol may be a pilot symbol, a symbol transmitting control information, a reference symbol, a symbol for frequency or time synchronization, or any kind of symbol.

(4,8,4)16APSK symbols may be symbols for transmitting data and may be pilot symbols as described in embodiment 2.

When a (4,8,4)16APSK symbol is a symbol for transmitting data, (4,8,4)16APSK mapping described in embodiment 8 is performed to obtain an in-phase component and quadrature component of a baseband signal from four bits of data, b₃, b₂, b₁, and b₀.

As above, when a modulation scheme of a data symbol is (4,8,4)16APSK, PAPR is low and therefore occurrence of intersymbol interference is reduced and, when compared to (12,4)16APSK, (4,8,4)16APSK is preferred for constellation and labelling, and therefore a receive apparatus is likely to achieve high data reception quality.

In this case, when the constellation described in embodiment 9 is applied to (4,8,4)16APSK, the probability of achieving higher data reception quality becomes higher. Specific examples are as follows.

[1] Satisfying <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[2] Satisfying <Condition 11> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[3] Satisfying <Condition 12> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[4] Satisfying <Condition 9> and <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[5] Satisfying <Condition 9> and <Condition 11> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[6] Satisfying <Condition 9> and <Condition 12> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[7] Satisfying <Condition 10> and λ=π/12 radians for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[8] Satisfying <Condition 11> and λ=π/12 radians for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[9] Satisfying <Condition 12> and λ=π/12 radians for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[10] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[11] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 11> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[12] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 12> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[13] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 9> and <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[14] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 9> and <Condition 11> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[15] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 9> and <Condition 12> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[16] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 10> and λ=π/12 radians for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[17] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 11> and λ=π/12 radians for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[18] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 12> and λ=π/12 radians for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[19] Satisfying <Condition 9> and <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

[20] Satisfying <Condition 7> and <Condition 8>, and satisfying <Condition 9> and <Condition 10> for arrangement of constellation points (coordinates of constellation points) of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane as described in embodiment 8. (R₁<R₂<R₃)

(Embodiment 11)

<Example of Pilot Symbols>

In the present embodiment, an example of pilot symbol configuration is described in the transmission scheme described in embodiment 10 (the modulation scheme of data symbols is (4,8,4)16APSK).

Note that the transmit apparatus in the present embodiment is identical to the transmit apparatus described in embodiment 1 and therefore description thereof is omitted here. However, (4,8,4)16APSK is used instead of (8,8)16APSK.

Intersymbol interference occurs for modulated signals because of non-linearity of the power amplifier of the transmit apparatus. High data reception quality can be achieved by a receive apparatus by decreasing this intersymbol interference.

In the present example of pilot symbol configuration, in order to reduce intersymbol interference at a receive apparatus, when data symbols are configured so that “two or more (4,8,4)16APSK symbols are consecutive”, a transmit apparatus generates and transmits, as pilot symbols, all baseband signals corresponding to all possible constellation points of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane (in other words, baseband signals corresponding to 16 constellation points of four transmit bits [b₃b₂b₁b₀], from [0000] to [1111]). Thus, a receive apparatus can estimate intersymbol interference for all possible constellation points of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane, and therefore achieving high data reception quality is likely.

Specifically, the following are transmitted as pilot symbols (reference symbols), in order:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (4,8,4)16APSK; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (4,8,4)16APSK.

The above feature means that:

<1> Symbols corresponding to all constellation points of (4,8,4)16APSK on an in-phase (I)-quadrature-phase (Q) plane, i.e., the following symbols, are transmitted in any order:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (4,8,4)16APSK; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (4,8,4)16APSK.

Pilot symbols need not be symbols only for estimating intersymbol interference, and a receive apparatus may estimate a radio wave propagation environment between a transmit apparatus and the receive apparatus (channel estimation), and may estimate frequency offset using the pilot symbols.

Further, a transmission method of pilot symbols is not limited to the above. Above, the pilot symbols are configured as 16 symbols, but when, for example, the pilot symbols are configured as 16×N symbols (N being a natural number), there is an advantage that the number of occurrences of each of the following symbols can be equalized:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (4,8,4)16APSK;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (4,8,4)16APSK; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (4,8,4)16APSK.

(Embodiment 12)

<Signaling>

In the present embodiment, examples are described of various information signaled as TMCC information in order to facilitate reception at the receive apparatus of a transmit signal used in the transmission scheme described in embodiment 10.

Note that the transmit apparatus in the present embodiment is identical to the transmit apparatus described in embodiment 1 and therefore description thereof is omitted here. However, (4,8,4)16APSK is used instead of (8,8)16APSK.

FIG. 18 illustrates a schematic of a frame of a transmit signal of advanced wide band digital satellite broadcasting (however, FIG. 18 is not intended to be an exact illustration of a frame of advanced wide band digital satellite broadcasting). Note that details are described in embodiment 3, and therefore description is omitted here.

Table 9 illustrates a configuration of modulation scheme information. In table 9, for example, when four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0001], a modulation scheme for generating symbols of “slots composed of a symbol group” is π/2 shift binary phase shift keying (BPSK).

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0010], a modulation scheme for generating symbols of “slots composed of a symbol group” is quadrature phase shift keying (QPSK).

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0011], a modulation scheme for generating symbols of “slots composed of a symbol group” is 8 phase shift keying (8PSK).

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0100], a modulation scheme for generating symbols of “slots composed of a symbol group” is (12,4)16APSK.

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0101], a modulation scheme for generating symbols of “slots composed of a symbol group” is (4,8,4)16APSK.

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0110], a modulation scheme for generating symbols of “slots composed of a symbol group” is 32 amplitude phase shift keying (32APSK).

. . .

TABLE 9 Modulation scheme information Value Assignment 0000 Reserved 0001 π/2 shift BPSK 0010 QPSK 0011 8PSK 0100 (12,4)16APSK 0101 (4,8,4)16APSK 0110 32APSK 0111 . . . . . . . . . 1111 No scheme assigned

Table 10 illustrates a relationship between coding rates of error correction code and ring ratios when a modulation scheme is (12,4)16APSK. According to R₁ and R₂, used above to represent constellation points in an I-Q plane of (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is represented as R_((12,4))=R₂/R₁. In Table 10, for example, when four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0000], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 41/120 (≈1/3), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is 3.09.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0001], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 49/120 (≈2/5), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is 2.97.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0010], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 61/120 (≈1/2), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is 3.93.

. . .

TABLE 10 Relationship between coding rates of error correction code and ring ratios when modulation scheme is (12,4)16APSK Coding rate Ring Value (approximate value) ratio 0000 41/120 (1/3) 3.09 0001 49/120 (2/5) 2.97 0010 61/120 (1/2) 3.93 . . . . . . . . . 1111 No scheme assigned —

Table 11 indicates a relationship between coding rate of error correction code and radii/phases, when a modulation scheme is (4,8,4)16APSK.

In Table 11, for example, when four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0000], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 41/120 (≈1/3), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (4,8,4)16APSK, R₁=1.00, R₂=2.00, R₃=2.20, and phase λ=π/12 radians.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0001], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 49/120 (≈2/5), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (4,8,4)16APSK, R₁=1.00, R₂=2.10, R₃=2.20, and phase λ=π/12 radians.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0010], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 61/120 (≈1/2), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (4,8,4)16APSK, R₁=1.00, R₂=2.20, R₃=2.30, and phase λ=π/10 radians.

. . .

TABLE 11 Relationship between radii/phases of error correction coding and ring ratios when modulation scheme is (4,8,4)16APSK Coding rate Value (approximate value) Radii and phase 0000 41/120 (1/3) R₁ = 1.00, R₂ = 2.00, R₃ = 2.20, λ = π/12 0001 49/120 (2/5) R₁ = 1.00, R₂ = 2.10, R₃ = 2.20, λ = π/12 0010 61/120 (1/2) R₁ = 1.00, R₂ = 2.20, R₃ = 2.30, λ = π/10 . . . . . . . . . 1111 No scheme assigned —

<Receive Apparatus>

The following describes operation of a receive apparatus that receives a radio signal transmitted by the transmit apparatus 700, with reference to the diagram of a receive apparatus in FIG. 19.

The receive apparatus 1900 of FIG. 19 receives a radio signal transmitted by the transmit apparatus 700 via the antenna 1901. The RF receiver 1902 performs processing such as frequency conversion and quadrature demodulation on a received radio signal, and outputs a baseband signal.

The demodulator 1904 performs processing such as root roll-off filter processing, and outputs a post-filter baseband signal.

The synchronization and channel estimator 1914 receives a post-filter baseband signal as input, performs time synchronization, frequency synchronization, and channel estimation, using, for example, a “synchronization symbol group” and “pilot symbol group” transmitted by the transmit apparatus, and outputs an estimated signal.

The control information estimator 1916 receives a post-filter baseband signal as input, extracts symbols including control information such as a “TMCC information symbol group”, performs demodulation and decoding, and outputs a control signal.

Of importance in the present embodiment is that a receive apparatus demodulates and decodes a symbol transmitting “transmission mode modulation scheme” information and a symbol transmitting “transmission mode coding rate” of “transmission mode/slot information” of a “TMCC information symbol group”; and, based on Table 9, Table 10, and Table 11, the control information estimator 1916 generates modulation scheme information and error correction code scheme (for example, coding rate of error correction code) information used by “slots composed of a data symbol group”, and generates ring ratio and radii/phase information when a modulation scheme used by “slots composed of a data symbol group” is (12,4)16APSK, (4,8,4)16APSK, or 32APSK, and outputs the information as a portion of a control signal.

The de-mapper 1906 receives a post-filter baseband signal, control signal, and estimated signal as input, determines a modulation scheme (or transmission method) used by “slots composed of a data symbol group” based on the control signal (in this case, when there is a ring ratio and radii/phase, determination with respect to the ring ratio and radii/phase is also performed), calculates, based on this determination, a log-likelihood ratio (LLR) for each bit included in a data symbol from the post-filter baseband signal and estimated signal, and outputs the log-likelihood ratios. (However, instead of a soft decision value such as an LLR a hard decision value may be outputted, and a soft decision value instead of an LLR may be outputted.)

The de-interleaver 1908 receives log-likelihood ratios as input, accumulates input, performs de-interleaving (permutes data) corresponding to interleaving used by the transmit apparatus, and outputs post-de-interleaving log-likelihood ratios.

The error correction decoder 1912 receives post-de-interleaving log-likelihood ratios and a control signal as input, determines error correction code used (code length, coding rate, etc.), performs error correction decoding based on this determination, and obtains estimated information bits. When the error correction code being used is an LDPC code, belief propagation (BP) decoding methods such as sum-product decoding, shuffled belief propagation (BP) decoding, and layered BP decoding may be used as a decoding method.

The above describes operation when iterative detection is not performed. The following is supplemental description of operation when iterative detection is performed. Note that a receive apparatus need not implement iterative detection, and a receive apparatus may be a receive apparatus that performs initial detection and error detection decoding without being provided with elements related to iterative detection that are described below.

When iterative detection is performed, the error correction decoder 1912 outputs a log-likelihood ratio for each post-decoding bit (note that when only initial detection is performed, output of a log-likelihood ratio for each post decoding bit is not necessary).

The interleaver 1910 interleaves log-likelihood ratios of post-decoding bits (performs permutation), and outputs post-interleaving log-likelihood ratios.

The de-mapper 1906 performs iterative detection by using post-interleaving log-likelihood ratios, a post-filter baseband signal, and an estimated signal, and outputs a log-likelihood ratio for each post-iterative detection bit.

Subsequently, interleaving and error correction code operations are performed. Thus, these operations are iteratively performed. In this way, finally the possibility of achieving a preferable decoding result is increased.

In the above description, a feature thereof is that by a reception apparatus obtaining a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” and a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group”, a modulation scheme and coding rate of error detection coding are estimated, and, when a modulation scheme is 16APSK, 32APSK, ring ratios and radii/phases are estimated, and demodulation and decoding operations become possible.

The above description describes the frame configuration in FIG. 18, but frame configurations applicable to the present invention are not limited in this way. When a plurality of data symbols exist, a symbol exists for transmitting information related to a modulation scheme used in generating the plurality of data symbols, and a symbol exists for transmitting information related to an error correction scheme (for example, error correction code used, code length of error correction code, coding rate of error correction code, etc.) used in generating the plurality of data symbols, any arrangement in a frame may be used with respect to the plurality of data symbols, the symbol for transmitting information related to a modulation scheme, and the symbol for transmitting information related to an error correction scheme. Further, symbols other than these symbols, for example a symbol for preamble and synchronization, pilot symbols, a reference symbol, etc., may exist in a frame.

In addition, as a method different to that described above, a symbol transmitting information related to ring ratios and radii/phases may exist, and the transmit apparatus may transmit the symbol. An example of a symbol transmitting information related to ring ratios and radii/phases is illustrated below.

TABLE 12 Example of symbol transmitting information related to ring ratios and radii/phases Value Assignment 00000 (12,4)16APSK ring ratio 4.00 00001 (12,4)16APSK ring ratio 4.10 00010 (12,4)16APSK ring ratio 4.20 00011 (12,4)16APSK ring ratio 4.30 00100 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.00, R₃ = 2.20, λ = π/12 00101 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.10, R₃ = 2.20, λ = π/12 00110 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.20, R₃ = 2.30, λ = π/10 00111 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.20, R₃ = 2.30, λ = π/12 . . . . . . 11111 . . .

In Table 12, when [00000] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00”.

Further, the following is true.

When [00001] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10”.

When [00010] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.20”.

When [00011] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.30”.

When [00100] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.00, R₃=2.20, λ=π/12”.

When [00101] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.10, R₃=2.20, λ=π/12”.

When [00110] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.20, R₃=2.30, λ=π/10”.

When [00111] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.20, R₃=2.30, λ=7π/12”.

Thus, by obtaining a symbol transmitting information related to ring ratio and radii/phases, a receive apparatus can estimate a ring ratio and radii/phases used by a data symbol, and therefore demodulation and decoding of the data symbol becomes possible.

Further, ring ratio and radii/phases information may be included in a symbol for transmitting a modulation scheme. An example is illustrated below.

TABLE 13 Modulation scheme information Value Assignment 00000 (12,4)16APSK ring ratio 4.00 00001 (12,4)16APSK ring ratio 4.10 00010 (12,4)16APSK ring ratio 4.20 00011 (12,4)16APSK ring ratio 4.30 00100 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.00, R₃ = 2.20, λ = π/12 00101 (4,8, 4)16APSK R₁ = 1.00, R₂ = 2.10, R₃ = 2.20, λ = π/12 00110 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.20, R₃ = 2.30, λ = π/10 00111 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.20, R₃ = 2.30, λ = π/12 . . . . . . 11101 8PSK 11110 QPSK 11111 π/2 shift BPSK

In Table 13, when [00000] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00”.

Further, the following is true.

When [00001] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10”.

When [00010] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.20”.

When [00011] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.30”.

When [00100] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.00, R₃=2.20, λ=π/12”.

When [00101] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.10, R₃=2.20, λ=π/12”.

When [00110] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.20, R₃=2.30, λ=π/10”.

When [00111] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.20, R₃=2.30, λ=π/12”.

When [11101] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “8PSK”.

When [11110] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “QPSK”.

When [11111] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “π/2 shift BPSK”.

Thus, by obtaining a symbol transmitting modulation scheme information, a receive apparatus can estimate a modulation scheme, ring ratio, radii, and phases used by a data symbol, and therefore demodulation and decoding of the data symbol becomes possible.

Note that in the above description, examples are described including “(12,4)16APSK” and “(4,8,4)16APSK” as selectable modulation schemes (transmission methods), but modulation schemes (transmission methods) are not limited to these examples. In other words, other modulation schemes may be selectable.

(Embodiment 13)

In the present embodiment, an order of generation of a data symbol is described.

FIG. 18, part (a) illustrates a schematic of a frame configuration. In FIG. 18, part (a), the “#1 symbol group”, the “#2 symbol group”, the “#3 symbol group”, . . . are lined up. Each symbol group among the “#1 symbol group”, the “#2 symbol group”, the “#3 symbol group”, . . . is herein composed of a “synchronization symbol group”, a “pilot symbol group”, a “TMCC information symbol group”, and “slots composed of a data symbol group”, as illustrated in FIG. 18, part (a).

Here, a configuration scheme is described of data symbol groups in each “slots composed of a data symbol group” among, for example, N symbol groups including the “#1 symbol group”, the “#2 symbol group”, the “#3 symbol group”, . . . , an “#N−1 symbol group”, an “#N symbol group”.

A rule is provided with respect to generation of data symbol groups in each “slots composed of a data symbol group” among N symbol groups from a “#(β×N+1) symbol group” to a “#(β×N+N) symbol group”. The rule is described with reference to FIG. 37.

Thus, a data symbol group of (4,8,4)16APSK of FIG. 37 satisfies features of FIG. 37, part (a), to FIG. 37, part (f). Note that in FIG. 37, the horizontal axis is symbols.

FIG. 37, part (a):

When a 32APSK data symbol exists and a (12,4)16APSK data symbol does not exist, a “(4,8,4)16APSK data symbol” exists after a “32APSK data symbol”, as illustrated in FIG. 37, part (a).

FIG. 37, part (b):

When a (12,4)16APSK data symbol exists, a “(4,8,4)16APSK data symbol” exists after a “(12,4)16APSK data symbol”, as illustrated in FIG. 37, part (b).

FIG. 37, part (c):

When a (12,4)16APSK data symbol exists, a “(12,4)16APSK data symbol” exists after a “(4,8,4)16APSK data symbol”, as illustrated in FIG. 37, part (b).

Either FIG. 37, part (b), or FIG. 37, part (c) may be satisfied.

FIG. 37, part (d):

When an 8PSK data symbol exists and a (12,4)16APSK data symbol does not exist, an “8PSK data symbol” exists after a “(4,8,4)16APSK data symbol”, as illustrated in FIG. 37, part (d).

FIG. 37, part (e):

When an QPSK data symbol exists, an 8PSK data symbol does not exist, and a (12,4)16APSK data symbol does not exist, a “QPSK data symbol” exists after a “(4,8,4)16APSK data symbol”, as illustrated in FIG. 37, part (e).

FIG. 37, part (f):

When a π/2 shift BPSK data symbol exists, a QPSK data symbol does not exist, an 8PSK data symbol does not exist, and a (12,4)16APSK data symbol does not exist, a “π/2 shift BPSK data symbol” exists after a “(4,8,4)16APSK data symbol”, as illustrated in FIG. 37, part (f).

When symbols are arranged as described above, there is an advantage that a receive apparatus can easily perform automatic gain control (AGC) because a signal sequence is arranged in order of modulation schemes (transmission methods) of high peak power.

FIG. 38 illustrates an example configuration method of the “(4,8,4)16APSK data symbol” described above.

Assume that a “(4,8,4)16APSK data symbol” of a coding rate X of error correction code and a “(4,8,4)16APSK data symbol” of a coding rate Y of error correction code exist. Also assume that a relationship X>Y is satisfied.

Thus, a “(4,8,4)16APSK data symbol” of a coding rate Y of error correction code is arranged after a “(4,8,4)16APSK data symbol” of a coding rate X of error correction code.

As in FIG. 38, assume that a “(4,8,4)16APSK data symbol” of a coding rate 1/2 of error correction code, a “(4,8,4)16APSK data symbol” of a coding rate 2/3 of error correction code, and a “(4,8,4)16APSK data symbol” of a coding rate 3/4 of error correction code exist. Thus, from the above description, as illustrated in FIG. 38, symbols are arranged in the order of a “(4,8,4)16APSK data symbol” of a coding rate 3/4 of error correction code, a “(4,8,4)16APSK data symbol” of a coding rate 2/3 of error correction code, and a “(4,8,4)16APSK data symbol” of a coding rate 1/2 of error correction code.

(Embodiment A)

In the present embodiment, a scheme is described that can select a ring ratio (for example, a (12,4)16APSK ring ratio) even when a coding rate of error correction code is a given coding rate (for example, coding rate is set to a value K). This scheme contributes to improvements in variation of patterns of switching modulation schemes, for example, and thereby a receive apparatus can achieve high data reception quality by setting suitable ring ratios.

Note that ring ratio (for example, (12,4)16APSK ring ratio) has been defined prior to the present embodiment, and ring ratio may also be referred to as “radius ratio”.

<Transmit Station>

FIG. 39 illustrates an example of a transmit station.

A transmit system A101 in FIG. 39 receives video data and audio data as input and generates a modulated signal according to a control signal A100.

The control signal A100 specifies code length of error correction code, coding rate, modulation scheme, and ring ratio.

An amplifier A102 receives a modulated signal as input, amplifies the modulated signal, and outputs a post-amplification transmit signal A103. The transmit signal A103 is transmitted via an antenna A104.

<Ring Ratio Selection>

Table 14 illustrates an example of coding rates of error correction code and ring ratios when a modulation scheme is (12,4)16APSK.

TABLE 14 Coding rates of error correction code and ring ratios when modulation scheme is (12,4)16APSK Coding rate Ring Value (approximate value) ratio 0000 41/120 (1/3) 2.99 0001 41/120 (1/3) 3.09 0010 41/120 (1/3) 3.19 0011 49/120 (2/5) 2.87 0100 49/120 (2/5) 2.97 0101 49/120 (2/5) 3.07 0110 61/120 (1/2) 3.83 . . . . . . . . . 1111 No scheme assigned —

A control signal generator (not illustrated) generates the control signal A100 for indicating a value of Table 14 according to a predefined coding rate and ring ratio of a transmit apparatus. At the transmit system A101, a modulated signal is generated according to a coding rate and ring ratio specified by the control signal A100.

For example, when a transmit apparatus specifies (12,4)16APSK as a modulation scheme, 41/120(≈1/3) as a coding rate of error correction code, and 2.99 as a ring ratio, four bits of control information related to bit ratio are “0000”. Further, when (12,4)16APSK is specified as a modulation scheme, 41/120(≈1/3) is specified as a coding rate of error correction code, and 3.09 is specified as a ring ratio, four bits of control information related to bit ratio are “0001”.

Thus, a transmit apparatus transmits “four bits of control information related to ring ratio” as a portion of control information.

Further, at a terminal that receives data (control information) containing four bit values of Table 14 (four bits of control information related to ring ratio), de-mapping (for example, log-likelihood ratio for each bit) is performed according to a coding rate and ring ratio indicated by the bit values, and data modulation, etc., is performed.

Transmission of this four bit value (four bits of control information related to ring ratio) can be performed using four bits within “transmission mode/slot information” with a “TMCC information symbol group”.

Table 14 indicates “in a case in which a symbol for transmitting a modulation scheme of a transmission mode indicates (12,4)16APSK, when values of four bits are “0000”, a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 41/120 (≈1/3) and a ring ratio of (12,4)16APSK is R_((12,4))=2.99”.

Further, “in a case in which a symbol for transmitting a modulation scheme of a transmission mode indicates (12,4)16APSK, when values of four bits are “0001”, a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 41/120 (≈1/3) and a ring ratio of (12,4)16APSK is R_((12,4))=3.09”.

Further. “in a case in which a symbol for transmitting a modulation scheme of a transmission mode indicates (12,4)16APSK, when values of four bits are “0010”, a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 41/120 (≈1/3) and a ring ratio of (12,4)16APSK is R_((12,4))=3.19”.

In this Table 14, for each coding rate value three types of ring ratio are assigned, but this is merely one example. In other words, for each coding rate value a plurality of types of ring ratio may be assigned. Further, a portion of coding rate values may be assigned one type of ring ratio, and remaining coding rate values may be assigned a plurality of types of ring ratio.

<Receive Apparatus>

A receive apparatus is described that corresponds to the transmission method of the present embodiment.

A receive apparatus (terminal) A200 of FIG. 40 receives, via an antenna A201, a radio signal transmitted by the transmit station of FIG. 39 and relayed by a satellite (repeater station). A relationship between the transmit station, repeated station, and receive apparatus (terminal) is described in the next embodiment.

An RF receiver A202 performs processing such as frequency conversion and quadrature demodulation on a received radio signal, and outputs a baseband signal.

A demodulator A204 performs processing such as root roll-off filter processing, and outputs a post-filter baseband signal.

A synchronization and channel estimator A214 receives a post-filter baseband signal as input, performs time synchronization, frequency synchronization, and channel estimation, using, for example, a “synchronization symbol group” and “pilot symbol group” transmitted by the transmit apparatus, and outputs an estimated signal.

A control information estimator A216 receives a post-filter baseband signal as input, extracts symbols including control information such as a “TMCC information symbol group”, performs demodulation and decoding, and outputs a control signal. Of importance to the present embodiment is that a symbol transmitting “transmission mode/slot information” of a “TMCC information symbol group” is demodulated and decoded by the receive apparatus A200. Thus, the control information estimator A216 generates information specifying a coding rate and ring ratio from values of four bits (four bits of control information related to ring ratio) decoded based on a table identical to Table 14 stored at the receive apparatus A200, and outputs the information as a portion of a control signal.

A de-mapper A206 receives a post-filter baseband signal, control signal, and estimated signal as input, determines, based on the control signal, a modulation scheme (or transmission method) and ring ratio used by “slots composed by a data symbol group”, calculates, based on this determination, a log-likelihood ratio (LLR) for each bit included in a data symbol from the post-filter baseband signal and the estimated signal, and outputs the LLRs. (However, instead of a soft decision value such as an LLR a hard decision value may be outputted, and a soft decision value instead of an LLR may be outputted.)

A de-interleaver A208 receives log-likelihood ratios and control signal as input, accumulates input, performs de-interleaving (permutes data) corresponding to interleaving used by the transmit apparatus, and outputs a post-de-interleaving log-likelihood ratio.

An error correction decoder A212 receives post-de-interleaving log-likelihood ratios and a control signal as input, determines error correction code used (code length, coding rate, etc.), performs error correction decoding based on this determination, and obtains estimated information bits. When the error correction code being used is an LDPC code, belief propagation (BP) decoding methods such as sum-product decoding, shuffled belief propagation (BP) decoding, and layered BP decoding may be used as a decoding method. The above describes operation when iterative detection is not performed, but the receive apparatus may perform iterative detection as described for the receiver apparatus of FIG. 2.

(Embodiment B)

The present embodiment describes a scheme that can select a ring ratio of (12,4)16APSK for each channel even when a coding rate of error correction code is set to a given value (for example, coding rate set as K). In the following, (12,4)16APSK is described as a modulation scheme that selects ring ratios, but modulation schemes that select ring ratios are not limited to (12,4)16APSK. Thus, by setting a suitable ring ratio for each channel, a receive apparatus can achieve high data reception quality.

FIG. 41 to FIG. 43 illustrate a terrestrial transmit station transmitting a transmit signal towards a satellite. FIG. 44 illustrates frequency allocation of each modulated signal. FIG. 45 and FIG. 46 illustrate examples of satellites (repeaters) that receive a signal transmitted by a terrestrial transmit station and transmit a modulated signal towards a terrestrial receive terminal.

Note that ring ratio (for example, (12,4)16APSK ring ratio) has been defined prior to the present embodiment, and ring ratio may also be referred to as “radius ratio”.

<Transmit Station>

FIG. 41 illustrates an example of a transmit station having a common (shared) amplifier.

N transmit systems B101_1 to B101_N of FIG. 41 each receive video data, audio data, and the control signal A100 as input.

The control signal A100 specifies code length of error correction code, coding rate, modulation scheme, and ring ratio for each channel. This modulation scheme is, for example, specified as (12,4)16APSK.

Transmit systems B101_1 to B101_N generate modulated signals according to the control signal A100.

A common (shared) amplifier B102 receives modulated signals #1 to #N as input, amplifies the modulated signals, and outputs a post-amplification transmit signal B103 including the modulated signals #1 to #N.

The transmit signal B103 is composed of a signal of N channels of modulated signals #1 to #N and includes a “TMCC information symbol group” for each channel (each modulated signal). These “TMCC information symbol groups” include ring ratio information in addition to code length of error correction code, coding rate and modulation scheme.

Specifically, modulated signal #1 includes “TMCC information symbol group” in modulated signal #1 (channel #1), modulated signal #2 includes “TMCC information symbol group” in modulated signal #2 (channel #2), . . . , modulated signal #N includes “TMCC information symbol group” in modulated signal #N (channel #N).

Transmit signal B103 is transmitted via antenna B104.

FIG. 42 illustrates an example of a transmit station having an amplifier for each transmit system channel.

N amplifiers B201_1 to B201_N amplify a modulated signal inputted thereto, and output transmit signals B202_1 to B202_N. Transmit signals B202_1 to B202_N are transmitted via antennas B203_1 to B203_N.

The transmit station of FIG. 43 is an example of a transmit station that has an amplifier for each transmit system channel, but transmits after mixing by a mixer.

A mixer B301 mixes post-amplification modulated signals outputted from the amplifiers B201_1 to B201_N, and transmits a post-mixing transmit signal B302 via an antenna B303.

<Frequency Allocation of Each Modulated Signal>

FIG. 44 illustrates an example of frequency allocation of signals (transmit signals or modulated signals) B401_1 to B401_N. In FIG. 44, the horizontal axis is frequency and the vertical axis is power. As illustrated in FIG. 44, B401_1 indicates a position on a frequency axis of transmit signal #1 (modulated signal #1) in FIG. 41, FIG. 42, and FIG. 43; B401_2 indicates a position on the frequency axis of transmit signal #2 (modulated signal #2) in FIG. 41, FIG. 42, and FIG. 43; . . . ; and B401_N indicates a position on the frequency axis of transmit signal #N (modulated signal #N) in FIG. 41, FIG. 42, and FIG. 43.

<Satellite>

Referring to the satellite of FIG. 45, a receive antenna B501 receives a signal transmitted by a transmit station, and outputs a receive signal B502. Here, the receive signal B502 includes components of modulated signal #1 to modulated signal #N in FIG. 41, FIG. 42, FIG. 43, and FIG. 44.

B503 in FIG. 45 is a radio processor. The radio processor B503 includes radio processing B503_1 to B503_N.

Radio processing B503_1 receives the receive signal B502 as input, performs signal processing such as amplification and frequency conversion with respect to components of modulated signal #1 in FIG. 41, FIG. 42, FIG. 43, and FIG. 44, and outputs a post-signal processing modulated signal #1.

Likewise, radio processing B503_2 receives the receive signal B502 as input, performs signal processing such as amplification and frequency conversion with respect to components of modulated signal #2 in FIG. 41, FIG. 42, FIG. 43, and FIG. 44, and outputs a post-signal processing modulated signal #2.

. . .

Likewise, radio processing B503_N receives the receive signal B502 as input, performs signal processing such as amplification and frequency conversion with respect to components of modulated signal #N in FIG. 41, FIG. 42, FIG. 43, and FIG. 44, and outputs a post-signal processing modulated signal #N.

An amplifier B504_1 receives the post-signal processing modulated signal #1 as input, amplifies the post-signal processing modulated signal #1, and outputs a post-amplification modulated signal #1.

An amplifier B504_2 receives the post-signal processing modulated signal #2 as input, amplifies the post-signal processing modulated signal #2, and outputs a post-amplification modulated signal #2.

. . .

An amplifier B504_N receives the post-signal processing modulated signal #N as input, amplifies the post-signal processing modulated signal #N, and outputs a post-amplification modulated signal #N.

Thus, each post-amplification modulated signal is transmitted via a respective one of antennas B505_1 to B505_N. (A transmitted modulated signal is received by a terrestrial terminal.) Here, frequency allocation of signals transmitted by a satellite (repeater) is described with reference to FIG. 44.

As previously described, referring to FIG. 44, B401_1 indicates a position on the frequency axis of transmit signal #1 (modulated signal #1) in FIG. 41, FIG. 42, and FIG. 43; B401_2 indicates a position on the frequency axis of transmit signal #2 (modulated signal #2) in FIG. 41, FIG. 42, and FIG. 43; . . . ; and B401_N indicates a position on the frequency axis of transmit signal #N (modulated signal #N) in FIG. 41, FIG. 42, and FIG. 43. Here, a frequency band being used is assumed to be a GHz.

Referring to FIG. 44, B401_1 indicates a position on the frequency axis of modulated signal #1 transmitted by the satellite (repeater) in FIG. 45; B401_2 indicates a position on the frequency axis of modulated signal #2 transmitted by the satellite (repeater) in FIG. 45; . . . ; and B401_N indicates a position on the frequency axis of modulated signal #N transmitted by the satellite (repeater) in FIG. 45. Here, a frequency band being used is assumed to be β GHz.

A satellite in FIG. 46 is different from the satellite in FIG. 45 in that a signal is transmitted after mixing at a mixer B601. Thus, the mixer B601 receives a post-amplification modulated signal #1, a post-amplification modulated signal #2, . . . , a post-amplification modulated signal #N as input, and generates a post-mixing modulated signal. Here, the post-mixing modulated signal includes a modulated signal #1 component, a modulated signal #2 component, . . . , and a modulated signal #N component, frequency allocation is as in FIG. 44, and is a signal in β GHz.

<Ring Ratio Selection>

Referring to the satellite systems described in FIG. 41 to FIG. 46, (12,4)16APSK ring ratio (radius ratio) is described as being selected for each channel from channel #1 to channel #N.

For example, when a code length (block length) of error correction code is X bits, among a plurality of selectable coding rates, a coding rate A (for example, 3/4) is selected.

Referring to the satellite systems in FIG. 45 and FIG. 46, when distortion of the amplifiers B504_1, B504_2, . . . , B504_N is low (linearity of input and output is high), even when a ring ratio (radius ratio) of (12,4)16APSK is uniquely defined, as long as a suitable value is determined a (terrestrial) terminal (receive apparatus) can achieve high data reception quality.

In satellite systems, amplifiers that can achieve high output are used in order to transmit modulated signals to terrestrial terminals. Thus, high-distortion amplifiers (linearity of input and output is low) are used, and the likelihood of distortion varying between amplifiers is high (distortion properties (input/output properties) of the amplifiers B504_1, B504_2, . . . , B504_N are different).

In this case, use of suitable (12,4)16APSK ring ratios (radius ratios) for each amplifier, i.e., selecting a suitable (12,4)16APSK ring ratio (radius ratio) for each channel, enables high data reception quality for each channel at a terminal. The transmit stations in FIG. 41, FIG. 42, and FIG. 43 perform this kind of setting by using the control signal A100.

Accordingly, information related to (12,4)16APSK ring ratios is included in, for example, control information such as TMCC that is included in each modulated signal (each channel). (This point is described in the previous embodiment.)

Accordingly, when the (terrestrial) transmit station in FIG. 41, FIG. 42, and FIG. 43 uses (12,4)16APSK as a modulation scheme of a data symbol of modulated signal #1, ring ratio information of the (12,4)16APSK is transmitted as a portion of control information.

Likewise, when the (terrestrial) transmit station in FIG. 41, FIG. 42, and FIG. 43 uses (12,4)16APSK as a modulation scheme of a data symbol of modulated signal #2, ring ratio information of the (12,4)16APSK is transmitted as a portion of control information.

Likewise, when the (terrestrial) transmit station in FIG. 41, FIG. 42, and FIG. 43 uses (12,4)16APSK as a modulation scheme of a data symbol of modulated signal #N, ring ratio information of the (12,4)16APSK is transmitted as a portion of control information.

. . .

A coding rate of error correction code used in modulated signal #1, a coding rate of error correction code used in modulated signal #2, . . . , and a coding rate of error correction code used in modulated signal #N may be identical.

<Receive Apparatus>

A receive apparatus is described that corresponds to the transmission method of the present embodiment.

The receive apparatus (terminal) A200 of FIG. 40 receives, via the antenna A201, a radio signal transmitted by the transmit station in FIG. 41 and FIG. 42 and relayed by a satellite (repeater station). The RF receiver A202 performs processing such as frequency conversion and quadrature demodulation on a received radio signal, and outputs a baseband signal.

The demodulator A204 performs processing such as root roll-off filter processing, and outputs a post-filter baseband signal.

The synchronization and channel estimator A214 receives a post-filter baseband signal as input, performs time synchronization, frequency synchronization, and channel estimation, using, for example, a “synchronization symbol group” and “pilot symbol group” transmitted by the transmit apparatus, and outputs an estimated signal.

The control information estimator A216 receives a post-filter baseband signal as input, extracts symbols including control information such as a “TMCC information symbol group”, performs demodulation and decoding, and outputs a control signal. Of importance to the present embodiment is that a symbol transmitting “TMCC information symbol group” information is demodulated and decoded by the receive apparatus A200. Thus, the control information estimator A216 generates information specifying a code length of error correction code, coding rate, modulation scheme, and ring ratio per channel, from values decoded at the receive apparatus A200, and outputs the information as a portion of a control signal.

The de-mapper A206 receives a post-filter baseband signal, control signal, and estimated signal as input, determines, based on the control signal, a modulation scheme (or transmission method) and ring ratio used by “slots composed by a data symbol group”, calculates, based on this determination, a log-likelihood ratio (LLR) for each bit included in a data symbol from the post-filter baseband signal and the estimated signal, and outputs the LLRs. (However, instead of a soft decision value such as an LLR a hard decision value may be outputted, and a soft decision value may be outputted instead of an LLR.) The de-interleaver A208 receives log-likelihood ratios and a control signal as input, accumulates input, performs de-interleaving (permutes data) corresponding to interleaving used by the transmit apparatus, and outputs a post-de-interleaving log-likelihood ratio.

The error correction decoder A212 receives post-de-interleaving log-likelihood ratios and a control signal as input, determines error correction code used (code length, coding rate, etc.), performs error correction decoding based on this determination, and obtains estimated information bits. When the error correction code being used is an LDPC code, belief propagation (BP) decoding methods such as sum-product decoding, shuffled belief propagation (BP) decoding, and layered BP decoding may be used as a decoding method. The above describes operation when iterative detection is not performed, but the receive apparatus may perform iterative detection as described for the receiver apparatus of FIG. 2.

A method of generating ring ratio information included in control information is not limited to the embodiment described prior to the present embodiment, and information related to ring ratios may be transmitted by any means.

(Embodiment C)

The present embodiment describes signaling (method of transmitting control information) for notifying a terminal of a ring ratio (for example (12,4)16APSK ring ratio).

Note that ring ratio (for example, (12,4)16APSK ring ratio) has been defined prior to the present embodiment, and ring ratio may also be referred to as “radius ratio”.

Signaling as above can be performed by using bits included in a “TMCC information symbol group” as described in the present description.

In the present embodiment, an example of configuring a “TMCC information symbol group” is based on Transmission System for Advanced Wide Band Digital Satellite Broadcasting, ARIB Standard STD-B44, Ver. 1.0 (Non-Patent Literature 2).

Information related to ring ratios for a transmit station to notify a terminal via a satellite (repeater) may accompany use of the 3614 bits of “extended information” within a “TMCC information symbol group” described with reference to FIG. 18. (This point is also disclosed in Transmission System for Advanced Wide Band Digital Satellite Broadcasting, ARIB Standard STD-B44, Ver. 1.0 (Non-Patent Literature 2).) This is illustrated in FIG. 47.

Extended information in FIG. 47 is a field used for conventional TMCC extended information, and is composed of 16 bits of an extended identifier and 3598 bits of an extended region. In “extended information” of TMCC in FIG. 47, when “scheme A” is applied, the extended identifier is all “0” (all 16 bits are zero) and the 3598 bits of the extended region are “1”.

Further, when “scheme B” is applied, bits of the extended identifier have values other than all “0”, i.e., values other than “0000000000000000”, as TMCC information is extended. Whether scheme A or scheme B is applied may for example be determined by user settings.

“Scheme A” is a transmission scheme (for example, satellite digital broadcast) that determines a ring ratio when a coding rate of error correction code is set to a given value. (Ring ratio is uniquely determined when a coding rate of error correction code to be used is determined.)

“Scheme B” is a transmission scheme (for example, satellite digital broadcast) that can select a ring ratio to use from a plurality of ring ratios each time a coding rate of error correction code is set to a given value.

The following describes examples of signaling performed by a transmit station, with reference to FIG. 48 to FIG. 52, but in all the examples the following bits are used in signaling.

d₀: Indicates a scheme of satellite broadcasting.

c₀c₁c₂c₃: Indicate a table.

b₀b₁b₂b₃: Indicate coding rate (may also indicate ring ratio).

x₀x₁x₂x₃x₄x₅: Indicate ring ratio.

y₀y₁y₂y₃y₄y₅: Indicate difference of ring ratio.

Detailed description of the above bits is provided later.

The “coding rate” illustrated in FIG. 48, FIG. 49, FIG. 50, FIG. 51, and FIG. 52 is coding rate of error correction code, and although values of 41/120, 49/120, 61/120, and 109/120 are specifically illustrated, these value may be approximated as 41/120≈1/3, 49/120≈2/5, 61/120≈1/2, and 109/120≈9/10.

The following describes <Example 1> to <Example 5>.

Referring to extended information in FIG. 47, “scheme A” is selected when all bits of the extended identifier are “0” (all 16 bits are zero) and all 3598 bits of the extended region are “1”.

First, a case is described in which a transmit apparatus (transmit station) transmits a modulated signal using “scheme A”.

When a transmit apparatus (transmit station) selects (12,4)16APSK as a modulation scheme, a relationship between coding rate of error correction code and ring ratio of (12,4)16APSK is as follows.

TABLE 15 Relationship between coding rate and (12,4)16APSK ring ratio (radius ratio) when “scheme A” is selected. Ring Coding rate (approximate value) ratio 41/120 (1/3) 3.09 49/120 (2/5) 2.97 61/120 (1/2) 3.93 73/120 (3/5) 2.87 81/120 (2/3) 2.92 89/120 (3/4) 2.97 97/120 (4/5) 2.73 101/120 (5/6)  2.67 105/120 (7/8)  2.76 109/120 (9/10) 2.69

Accordingly, setting all bits of TMCC extended identifier to “0” (all 16 bits are zero) and setting all 3598 bits of TMCC extended region to “1” (a transmit apparatus transmits these values) enables a receive apparatus to determine that “scheme A” is selected, and further, coding rate information of error correction code is transmitted as a portion of TMCC. A receive apparatus can determine a (12,4)16APSK ring ratio from this information when (12,4)16APSK is used as a modulation scheme.

Specifically, b₀, b₁, b₂, and b₃ are used as described above. A relationship between b₀ b₁, b₂, b₃, and coding rate of error correction code is as follows.

TABLE 16 Relationship between b₁, b₂, b₃, b₄ and coding rate of error correction code Coding rate b₀b₁b₂b₃ (approximate value) 0000 41/120 (1/3) 0001 49/120 (2/5) 0010 61/120 (1/2) 0011 73/120 (3/5) 0100 81/120 (2/3) 0101 89/120 (3/4) 0110 97/120 (4/5) 0111 101/120 (5/6)  1000 105/120 (7/8)  1001 109/120 (9/10)

As in Table 16, when a transmit apparatus (transmit station) uses 41/120 as a coding rate of error correction code, (b₀b₁b_(b2)b₃)=(0000). Further, when 49/120 is used as a coding rate of error correction code, (b₀b₁b₂b₃)=(0001), . . . , when 109/120 is used as a coding rate of error correction code, (b₀b₁b₂b₃)=(1001). As a portion of TMCC, b₀, b₁, b₂, and b₃ are transmitted.

Accordingly, the following table can be made.

TABLE 17 Relationship between b₀, b₁, b₂, b₃, coding rate of error correction code, and ring ratio Coding rate Ring b₀b₁b₂b₃ (approximate value) ratio 0000 41/120 (1/3) 3.09 0001 49/120 (2/5) 2.97 0010 61/120 (1/2) 3.93 0011 73/120 (3/5) 2.87 0100 81/120 (2/3) 2.92 0101 89/120 (3/4) 2.97 0110 97/120 (4/5) 2.73 0111 101/120 (5/6)  2.67 1000 105/120 (7/8)  2.76 1001 109/120 (9/10) 2.69

As can be seen from Table 17:

When a transmit apparatus (transmit station) is set to (b₀b₁b₂b₃)=(0000), a coding rate of error correction code is 41/120, and when (12,4)16APSK is used, a ring ratio (radius ratio) is 3.09.

When a transmit apparatus (transmit station) is set to (b₀b₁b₂b₃)=(0001), a coding rate of error correction code is 49/120, and when (12,4)16APSK is used, a ring ratio (radius ratio) is 2.97.

When a transmit apparatus (transmit station) is set to (b₀b₁b₂b₃)=(0010), a coding rate of error correction code is 61/120, and when (12,4)16APSK is used, a ring ratio (radius ratio) is 3.93.

When a transmit apparatus (transmit station) is set to (b₀b₁b₂b₃)=(0011), a coding rate of error correction code is 73/120, and when (12,4)16APSK is used, a ring ratio (radius ratio) is 2.87.

When a transmit apparatus (transmit station) is set to (b₀b₁b₂b₃)=(0100), a coding rate of error correction code is 81/120, and when (12,4)16APSK is used, a ring ratio (radius ratio) is 2.92.

When a transmit apparatus (transmit station) is set to (b₀b₁b₂b₃)=(0101), a coding rate of error correction code is 89/120, and when (12,4)16APSK is used, a ring ratio (radius ratio) is 2.97.

When a transmit apparatus (transmit station) is set to (b₀b₁b₂b₃)=(0110), a coding rate of error correction code is 97/120, and when (12,4)16APSK is used, a ring ratio (radius ratio) is 2.73.

When a transmit apparatus (transmit station) is set to (b₀b₁b₂b₃)=(0111), a coding rate of error correction code is 101/120, and when (12,4)16APSK is used, a ring ratio (radius ratio) is 2.67.

When a transmit apparatus (transmit station) is set to (b₀b₁b₂b₃)=(1000), a coding rate of error correction code is 105/120, and when (12,4)16APSK is used, a ring ratio (radius ratio) is 2.76.

When a transmit apparatus (transmit station) is set to (b₀b₁b₂b₃)=(1001), a coding rate of error correction code is 109/120, and when (12,4)16APSK is used, a ring ratio (radius ratio) is 2.69.

Accordingly, a transmit apparatus (transmit station) implements:

-   -   Setting all bits of TMCC extended information to “0” (all 16         bits are zero) and all 3598 bits of TMCC extended region to “1”,         in order to notify a receive apparatus that “scheme A” is being         used.     -   Transmitting b₀b₁b₂b₃ in order that coding rate of error         correction code and (12,4)16APSK can be estimated.

The following describes a case in which a transmit apparatus (of a transmit station) transmits data using “scheme B”.

As described above, when “scheme B” is applied, bits of the extended identifier have values other than all “0”, i.e., values other than “0000000000000000”, as TMCC information is extended. Here, as an example, when “0000000000000001” is transmitted as an extended identifier, a transmit apparatus (of a transmit station) transmits data using “scheme B”.

When the 16 bits of an extended identifier are represented as d₁₅, d₁₄, d₁₃, d₁₂, d₁₁, d₁₀, d₉, d₈, d₇, d₆, d₅, d₄, d₃, d₂, d₁, d₀, in a case in which “scheme B” is applied, (d₁₅, d₁₄, d₁₃, d₁₂, d₁₁, d₁₀, d₉, d₈, d₇, d₆, d₅, d₄, d₃, d₂, d₁, d₀)=(0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1). (When “scheme B” is applied as described above it suffices that (d₁₅, d₁₄, d₁₃, d₁₂, d₁₁, d₁₀, d₉, d₈, d₇, d₆, d₅, d₄, d₃, d₂, d₁, d₀) are set to values other than (0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0), and are therefore not limited to the example of (d₁₅, d₁₄, d₁₃, d₁₂, d₁₁, d₁₀, d₉, d₈, d₇, d₆, d₅, d₄, d₃, d₂, d₁, d₀)=(0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1).)

As specific examples, <Example 1> to <Example 5> are described below.

EXAMPLE 1

In example 1, a plurality of ring ratios are prepared in a table of (12,4)16APSK ring ratios, and therefore different ring ratios can be set for one coding rate.

As an example a case is described in which “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 4.00” are set. (Note that it is assumed that (12,4)16APSK is selected as a modulation scheme.)

As illustrated in FIG. 48, table 1, table 2, . . . , table 16, in other words 16 tables, table 1 to table 16, are prepared.

Each table associates (b₀b₁b₂b₃) values as described above, coding rates of error correction codes, and (12,4)16APSK ring ratios with each other.

For example, in table 1, when a coding rate of error correction code for generating a data symbol is 41/120 and a (12,4)16APSK ring ratio is 3.09, (b₀b₁b₂b₃)=(0000). In the same way, when a coding rate of error correction code for generating a data symbol is 49/120 and a (12,4)16APSK ring ratio is 2.97, (b₀b₁b₂b₃)=(0001) . . . . . When a coding rate of error correction code for generating a data symbol is 109/120 and a (12,4)16APSK ring ratio is 3.09, (b₀b₁b₂b₃)=(1001).

In table 2, when a coding rate of error correction code for generating a data symbol is 41/120 and a (12,4)16APSK ring ratio is 4.00, (b₀b₁b₂b₃)=(0000). In the same way, when a coding rate of error correction code for generating a data symbol is 49/120 and a (12,4)16APSK ring ratio is 3.91, (b₀b₁b₂b₃)=(0001) . . . . . When a coding rate of error correction code for generating a data symbol is 109/120 and a (12,4)16APSK ring ratio is 3.60, (b₀b₁b₂b₃)=(1001).

. . .

In table 16, when a coding rate of error correction code for generating a data symbol is 41/120 and a (12,4)16APSK ring ratio is 2.59, (b₀b₁b₂b₃)=(0000). In the same way, when a coding rate of error correction code for generating a data symbol is 49/120 and a (12,4)16APSK ring ratio is 2.50, (b₀b₁b₂b₃)=(0001) . . . . . When a coding rate of error correction code for generating a data symbol is 109/120 and a (12,4)16APSK ring ratio is 2.23, (b₀b₁b₂b₃)=(1001).

In table 1 to table 16, although not described above, b₀b₁b₂b₃ values and (12,4)16APSK ring ratios are associated with each of coding rates of error correction code 41/120, 49/120, 61/120, 73/120, 81/120, 89/120, 97/120, 101/120, 105/120, and 109/120.

Further, as illustrated in FIG. 48, association between c₀c₁c₂c₃ values and table selected is performed. When table 1 is selected, (c₀,c₁,c₂,c₃)=(0,0,0,0), when table 2 is selected, (c₀,c₁,c₂,c₃)=(0,0,0,1), . . . , and when table 16 is selected, (c₀,c₁,c₂,c₃)=(1,1,1,1).

The following describes a method of setting, for example, “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 4.00”.

First, as above, “scheme B” is selected so d₀=“1” is set.

Further, as illustrated in FIG. 48, a first line of table 2 shows a coding rate 41/120 and a (12,4)16APSK ring ratio 4.00, and therefore b₀b₁b₂b₃=“0000”.

Accordingly, a value c₀c₁c₂c₃=“0001” for indicating table 2 among 16 tables, table 1 to 16.

Accordingly, when a transmit apparatus (transmit station) transmits a data symbol when “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 4.00”, the transmit apparatus transmits d₀=“1”, b₀b₁b₂b₃=“0000”, and c₀c₁c₂c₃=“0001” control information (a portion of TMCC information) along with the data symbol. Note that, as control information, transmission is also required of control information indicating that a modulation scheme of the data symbol is (12,4)16APSK.

In other words, in <Example 1>:

-   -   A plurality of tables are prepared that associates b₀b₁b₂b₃         values and (12,4)16APSK ring ratios with each of coding rates of         error correction code 41/120, 49/120, 61/120, 73/120, 81/120,         89/120, 97/120, 101/120, 105/120, and 109/120.     -   c₀c₁c₂c₃ indicates a used table and is transmitted by a transmit         apparatus (transmit station).

Thus, a transmit apparatus transmits ring ratio information of (12,4)16APSK used to generate a data symbol.

A method of setting (12,4)16APSK ring ratios when a transmit apparatus (transmit station) uses “scheme A” is as described prior to the description of <Example 1>.

EXAMPLE 2

Example 2 is a modification of <Example 1>.

The following describes a case in which a transmit apparatus (of a transmit station) selects “scheme B”. Here, a transmit apparatus (transmit station) selects “scheme B”, and therefore d₀=“1” is set, as indicated in FIG. 49.

Subsequently, the transmit apparatus (transmit station) sets a value of z₀. When a (12,4)16APSK ring ratio is set by the same method as “scheme A”, z₀=0 is set. When z₀=0 is set, a coding rate of error correction code is determined from b₀, b₁, b₂, b₃ in table 16 and (12,4)16APSK ring ratio is determined from table 15. (See Table 17)

When a (12,4)16APSK ring ratio is set by the same method as in Example 1, z₀=1 is set. Thus, (12,4)16APSK ring ratio is not determined based on table 15, but is determined in the way described in Example 1.

As an example a case is described in which “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 4.00” are set. (Note that it is assumed that (12,4)16APSK is selected as a modulation scheme and z₀=1.)

As illustrated in FIG. 49, table 1, table 2, . . . , table 16, in other words 16 tables, table 1 to table 16, are prepared.

Each table associates (b₀b₁b₂b₃) values as described above, coding rates of error correction code, and (12,4)16APSK ring ratios with each other.

For example, in table 1, when a coding rate of error correction code for generating a data symbol is 41/120 and a (12,4)16APSK ring ratio is 3.09, (b₀b₁b₂b₃)=(0000). In the same way, when a coding rate of error correction code for generating a data symbol is 49/120 and a (12,4)16APSK ring ratio is 2.97, (b₀b₁b₂b₃)=(0001) . . . . . When a coding rate of error correction code for generating a data symbol is 109/120 and a (12,4)16APSK ring ratio is 3.09, (b₀b₁b₂b₃)=(1001).

In table 2, when a coding rate of error correction code for generating a data symbol is 41/120 and a (12,4)16APSK ring ratio is 4.00, (b₀b₁b₂b₃)=(0000). In the same way, when a coding rate of error correction code for generating a data symbol is 49/120 and a (12,4)16APSK ring ratio is 3.91, (b₀b₁b₂b₃)=(0001) . . . . . When a coding rate of error correction code for generating a data symbol is 109/120 and a (12,4)16APSK ring ratio is 3.60, (b₀b₁b₂b₃)=(1001).

In table 16, when a coding rate of error correction code for generating a data symbol is 41/120 and a (12,4)16APSK ring ratio is 2.59, (b₀b₁b₂b₃)=(0000). In the same way, when a coding rate of error correction code for generating a data symbol is 49/120 and a (12,4)16APSK ring ratio is 2.50, (b₀b₁b₂b₃)=(0001) . . . . . When a coding rate of error correction code for generating a data symbol is 109/120 and a (12,4)12APSK ring ratio is 2.23, (b₀b₁b₂b₃)=(1001).

In table 1 to table 16, although not described above, b₀b₁b₂b₃ values and (12,4)16APSK ring ratios are associated with each of coding rates of error correction code 41/120, 49/120, 61/120, 73/120, 81/120, 89/120, 97/120, 101/120, 105/120, and 109/120.

Further, as illustrated in FIG. 49, association between c₀c₁c₂c₃ values and table selected is performed. When table 1 is selected, (c₀,c₁,c₂,c₃)=(0,0,0,0), when table 2 is selected, (c₀,c₁,c₂,c₃)=(0,0,0,1), . . . , and when table 16 is selected, (c₀,c₁,c₂,c₃)=(1,1,1,1).

The following describes a method of setting, for example, “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 4.00”.

First, as above, “scheme B” is selected so d₀=“1” is set. Further, z₀=1 is set.

Further, as illustrated in FIG. 49, a first line of table 2 shows a coding rate 41/120 and a (12,4)16APSK ring ratio 4.00, and therefore b₀b₁b₂b₃=“0000”.

Accordingly, a value c₀c₁c₂c₃=“0001” for indicating table 2 among 16 tables, table 1 to 16.

Accordingly, when a transmit apparatus (transmit station) transmits a data symbol so that “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 4.00”, the transmit apparatus transmits d₀=“1”, z₀=1, b₀b₁b₂b₃=“0000”, and c₀c₁c₂c₃=“0001” control information (a portion of TMCC information) along with the data symbol. Note that, as control information, transmission is also required of control information indicating that a modulation scheme of the data symbol is (12,4)16APSK.

A method of setting (12,4)16APSK ring ratios when a transmit apparatus (transmit station) uses “scheme A” is as described prior to the description of <Example 1>.

EXAMPLE 3

Example 3 is characterized by signaling being performed by a value indicating ring ratio.

First, as in <Example 1> and <Example 2>, a transmit apparatus (transmit station) transmits a modulated signal by “scheme B”, and therefore d₀=“1” is set.

Thus, as illustrated in FIG. 50, values of x₀x₁x₂x₃x₄x₅ and (12,4)16APSK ring ratios are associated with each other. For example, as illustrated in FIG. 50, when a transmit apparatus (transmit station) is set so that when (x₀,x₁,x₂,x₃,x₄,x₅)=(0,0,0,0,0,0), (12,4)16APSK ring ratio is set to 2.00, . . . , when (x₀,x₁,x₂,x₃,x₄,x₅)=(1,1,1,1,1,1), (12,4)16APSK ring ratio is set to 4.00.

As an example, the following describes a method of setting, for example, “satellite broadcasting scheme: “scheme B”, and (12,4)16APSK ring ratio: 2.00”.

In this example, a transmit apparatus (transmit station) sets x₀x₁x₂x₃x₄x₅=“000000” from “relationship between x₀x₁x₂x₃x₄x₅ value and (12,4)16APSK ring ratio” in FIG. 50.

Accordingly, when a transmit apparatus (transmit station) transmits a data symbol so that “satellite broadcast scheme: “scheme B” and (12,4)16APSK ring ratio: 2.00”, the transmit apparatus transmits d₀=“1” and x₀x₁x₂x₃x₄x₅=“000000” control information (a portion of TMCC information) along with the data symbol. Note that, as control information, transmission is also required of control information indicating that a modulation scheme of the data symbol is (12,4)16APSK.

A method of setting (12,4)16APSK ring ratios when a transmit apparatus (transmit station) uses “scheme A” is as described prior to the description of <Example 1>.

EXAMPLE 4

Example 4 implements signaling of a desired (12,4)16APSK ring ratio by b₀b₁b₂b₃, indicating coding rate of error correction code and (12,4)16APSK ring ratio in a main table, and y₀y₁y₂y₃y₄₅, indicating ring ratio difference.

An important point in Example 4 is that the main table illustrated in FIG. 51 is composed of the relationship between b₀,b_(i),b₂,b₃, coding rate of error correction code, and ring ratio from Table 17, in other words “scheme A”.

Further characterizing points of Example 4 are described below.

FIG. 51 illustrates a difference table. The difference table is a table for difference information from (12,4)16APSK ring ratios set using the main table. Based on the main table, a (12,4)16APSK ring ratio is, for example, set as h.

Thus, the following is true.

. . .

When a transmit apparatus (transmit station) sets (y₀y₁y₂y₃y₄y₅)=(011110), (12,4)16APSK ring ratio is set to h+0.4.

When a transmit apparatus (transmit station) sets (y₀y₁y₂y₃y₄y₅)=(011111), (12,4)16APSK ring ratio is set to h+0.2.

When a transmit apparatus (transmit station) sets (y₀y₁y₂y₃y₄y₅)=(100000), (12,4)16APSK ring ratio is set to h+0.

When a transmit apparatus (transmit station) sets (y₀y₁y₂y₃y₄y₅)=(100001), (12,4)16APSK ring ratio is set to h−0.2.

When a transmit apparatus (transmit station) sets (y₀y₁y₂y₃y₄y₅)=(100010), (12,4)16APSK ring ratio is set to h−0.4.

. . .

Accordingly, a transmit apparatus determines (y₀y₁y₂y₃y₄y₅) and thereby determines a correction value f with respect to a (12,4)16APSK ring ratio h determined by the main table, and sets a (12,4)16APSK ring ratio to h+f.

As an example, the following describes a method of setting “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 3.49”.

First, a transmit apparatus selects “scheme B” and therefore sets d₀=“1”.

Subsequently, the transmit apparatus sets b₀b₁b₂b₃=“0000” to select coding rate 41/120 from the main table of FIG. 51.

Since the (12,4)16APSK ring ratio corresponding to b₀b₁b₂b₃=“0000” in the main table is 3.09, the difference between the ring ratio 3.49 to be set and the ring ration 3.09 is 3.49-3.09=+0.4.

Thus, the transmit apparatus sets y₀y₁y₂y₃y₄y₅=“011110”, which indicates “+0.4” in the difference table.

Accordingly, when the transmit apparatus (transmit station) transmits a data symbol so that “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 3.49”, the transmit apparatus transmits d₀=“1”, b₀b₁b₂b₃=“0000”, y₀y₁y₂y₃y₄y₅=“011110” control information (a portion of TMCC information) along with the data symbol. Note that, as control information, transmission is also required of control information indicating that a modulation scheme of the data symbol is (12,4)16APSK.

Example 4 uses a portion of the main table of “scheme A” even when using “scheme B”, and therefore a portion of “scheme A” is suitable for use in “scheme B”.

Not that a method of setting (12,4)16APSK ring ratios when a transmit apparatus (transmit station) uses “scheme A” is as described prior to the description of <Example 1>.

In FIG. 51 a single difference table is provided but a plurality of difference tables may be provided. For example, difference table 1 to difference table 16 may be provided. Thus, as in FIG. 48 and FIG. 49, a difference table to be used may be selected by c₀c₁c₂c₃. Accordingly, a transmit apparatus sets c₀c₁c₂c₃ in addition to d₀, b₀b₁b₂b₃, and y₀y₁y₂y₃y₄y₅, and transmits c₀c₁c₂c₃ in addition to d₀, b₀b₁b₂b₃, and y₀y₁y₂y₃y₄y₅ as a portion of control information along with a data symbol.

Further, from a value of y₀y₁y₂y₃y₄y₅ in a difference table being used, a correction value f is obtained for a (12,4)16APSK ring ratio h determined by using the main table.

EXAMPLE 5

Example 5 implements signaling of a desired ring ratio by using b₀b₁b₂b₃, indicating coding rate of error correction code and (12,4)16APSK ring ratio in a main table, and y₀y₁y₂y₃y₄₅, indicating ring ratio difference.

An important point in Example 5 is that the main table illustrated in FIG. 52 is composed of the relationship between b₀,b_(i),b₂,b₃, coding rate of error correction code, and ring ratio from Table 17, in other words “scheme A”.

Further characterizing points of Example 5 are described below.

FIG. 52 illustrates a difference table. The difference table is a table for difference information from (12,4)16APSK ring ratios set using the main table. Based on the main table, a (12,4)16APSK ring ratio is, for example, set as h.

Thus, the following is true.

. . .

When a transmit apparatus (transmit station) sets (y₀y₁y₂y₃y₄y₅)=(011110), (12,4)16APSK ring ratio is set to h×1.2.

When a transmit apparatus (transmit station) sets (y₀y₁y₂y₃y₄y₅)=(011111), (12,4)16APSK ring ratio is set to h×1.1.

When a transmit apparatus (transmit station) sets (y₀y₁y₂y₃₄y₅)=(100000), (12,4)16APSK ring ratio is set to h×1.0.

When a transmit apparatus (transmit station) sets (y₀y₁y₂₃y₄y₅)=(100001), (12,4)16APSK ring ratio is set to h×0.9.

When a transmit apparatus (transmit station) sets (y₀y₁y₂y₃₄y₅)=(100010), (12,4)16APSK ring ratio is set to h×0.8.

. . .

Accordingly, a transmit apparatus determines (y₀y₁y₂y₃y₄y₅) and thereby determines a correction coefficient g with respect to a (12,4)16APSK ring ratio h determined by the main table, and sets a (12,4)16APSK ring ratio to h×g.

As an example, the following describes a method of setting “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 2.78”.

First, a transmit apparatus selects “scheme B” and therefore sets d₀=“1”.

Subsequently, the transmit apparatus sets b₀b₁b₂b₃=“0000” to select coding rate 41/120 from the main table of FIG. 52.

Since the (12,4)16APSK ring ratio corresponding to b₀b₁b₂b₃=“0000” in the main table is 3.09, the difference indicated by multiplication between the ring ratio to be set 2.78 and 3.09 is 2.78/3.09=0.9.

Thus, the transmit apparatus sets y₀y₁y₂y₃y₄y₅=“100001”, which indicates “×0.9” in the difference table.

Accordingly, when a transmit apparatus (transmit station) transmits a data symbol so that “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 2.78”, the transmit apparatus transmits d₀=“1”, b₀b₁b₂b₃=“0000”, and y₀₁y₂y₃y₄y₅=“100001” control information (portion of TMCC information) along with the data symbol. Note that, as control information, transmission is also required of control information indicating that a modulation scheme of the data symbol is (12,4)16APSK.

Example 5 uses a portion of the main table of “scheme A” even when using “scheme B”, and therefore a portion of “scheme A” is suitable for use in “scheme B”.

Not that a method of setting (12,4)16APSK ring ratios when a transmit apparatus (transmit station) uses “scheme A” is as described prior to the description of <Example 1>.

In FIG. 52 a single difference table is provided but a plurality of difference tables may be provided. For example, difference table 1 to difference table 16 may be provided. Thus, as in FIG. 48 and FIG. 49, a difference table to be used may be selected by c₀c₁c₂c₃. Accordingly, a transmit apparatus sets c₀c₁c₂c₃ in addition to d₀, b₀b₁b₂b₃, and y₀y₁y₂y₃y₄y₅, and transmits c₀c₁c₂c₃ in addition to d₀, b₀b₁b₂b₃, and y₀y₁y₂y₃y₄y₅ as a portion of control information along with a data symbol.

Further, from a value of y₀y₁y₂y₃y₄y₅ in a difference table being used, a correction coefficient g is obtained for a (12,4)16APSK ring ratio h determined by using the main table.

<Receive Apparatus>

The following describes configuration common to <Example 1> to <Example 5> of a receive apparatus corresponding to a transmission method of the present embodiment and subsequently describes specific processing for each example.

The terrestrial receive apparatus (terminal) A200 of FIG. 40 receives, via the antenna A201, a radio signal transmitted by the transmit station of FIG. 39 and relayed by a satellite (repeater station). The RF receiver A202 performs processing such as frequency conversion and quadrature demodulation on a received radio signal, and outputs a baseband signal.

The demodulator A204 performs processing such as root roll-off filter processing, and outputs a post-filter baseband signal.

The synchronization and channel estimator A214 receives a post-filter baseband signal as input, performs time synchronization, frequency synchronization, and channel estimation, using, for example, a “synchronization symbol group” and “pilot symbol group” transmitted by the transmit apparatus, and outputs an estimated signal.

The control information estimator A216 receives a post-filter baseband signal as input, extracts symbols including control information such as a “TMCC information symbol group”, performs demodulation and decoding, and outputs a control signal.

Of importance to the present embodiment is that control information included in “TMCC information symbol group” is estimated by the control information estimator A216 and outputted as a control signal, and that d₀, z₀, c₀c₁c₂c₃, b₀b₁b₂b₃, x₀x₁x₂x₃x₄x₅, and y₀y₁y₂y₃y₄y₅ information, described above, is included in the control signal.

The de-mapper A206 receives a post-filter baseband signal, control signal, and estimated signal as input, determines, based on the control signal, a modulation scheme (or transmission method) and ring ratio used by “slots composed by a data symbol group”, calculates, based on this determination, a log-likelihood ratio (LLR) for each bit included in a data symbol from the post-filter baseband signal and the estimated signal, and outputs the LLRs. (However, instead of a soft decision value such as an LLR a hard decision value may be outputted, and a soft decision value may be outputted instead of an LLR.)

The de-interleaver A208 receives log-likelihood ratios and a control signal as input, accumulates input, performs de-interleaving (permutes data) corresponding to interleaving used by the transmit apparatus, and outputs post-de-interleaving log-likelihood ratios.

The error correction decoder A212 receives post-de-interleaving log-likelihood ratios and a control signal as input, determines error correction code used (code length, coding rate, etc.), performs error correction decoding based on this determination, and obtains estimated information bits. When the error correction code being used is an LDPC code, belief propagation (BP) decoding methods such as sum-product decoding, shuffled belief propagation (BP) decoding, and layered BP decoding may be used as a decoding method. The above describes operation when iterative detection is not performed, but the receive apparatus may perform iterative detection as described for the receiver apparatus of FIG. 2.

Such a receive apparatus stores tables that are the same as the tables indicates in <Example 1> to <Example 5>, described above, and, by performing operations in reverse of that described in <Example 1> to <Example 5>, estimates a satellite broadcasting scheme, coding rate of error correction code, and (12,4)16APSK ring ratio, and performs demodulation and decoding. The following describes each example separately.

In the following, the control information estimator A216 of a receive apparatus is assumed to determine that a modulation scheme of a data symbol is (12,4)16APSK from TMCC information.

<<Receive Apparatus Corresponding to Example 1>>

-   -   When a transmit apparatus (transmit station) transmits a         modulated signal by “scheme A”:

When the control information estimator A216 of a receive apparatus obtains d₀=“0”, the control information estimator A216 determines that a data symbol is a symbol transmitted by “scheme A”. By obtaining a value of b₀b₁b₂b₃, when the data symbol is a (12,4)16APSK symbol, the control information estimator A216 estimates a (12,4)16APSK ring ratio. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

-   -   When a transmit apparatus (transmit station) transmits a         modulated signal by “scheme B”:

As illustrated in FIG. 53, the control information estimator A216 of the receive apparatus estimates “scheme B” from d₀=“1”, and a coding rate of error correction code 41/120 and (12,4)16APSK ring ratio 4.00 from line 1 of table 2 based on c₀c₁c₂c₃=“0001” and b₀b₁b₂b₃=“0000”. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

<<Receive Apparatus Corresponding to Example 2>>

-   -   When a transmit apparatus (transmit station) transmits a         modulated signal by “scheme A”:

When the control information estimator A216 of a receive apparatus obtains d₀=“0”, the control information estimator A216 determines that a data symbol is a symbol transmitted by “scheme A”. By obtaining a value of b₀b₁b₂b₃, when the data symbol is a (12,4)16APSK symbol, the control information estimator A216 estimates a (12,4)16APSK ring ratio. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

-   -   When a transmit apparatus (transmit station) transmits a         modulated signal by “scheme B”:

As illustrated in FIG. 54, the control information estimator A216 of the receive apparatus determines “set to same ring ratio as scheme A” when obtaining d₀=“1” and z₀=“0”, and estimates a coding rate of error correction code and (12,4)16APSK ring ratio from Table 17 when obtaining b₀b₁b₂b₃. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

Further, as illustrated in FIG. 54, the control information estimator A216 of the receive apparatus determines “set to ring ratio for scheme B” from d₀=“1” and z₀=“l”, and estimates a coding rate of error correction code 41/120 and (12,4)16APSK ring ratio 4.00 from line 1 of table 2 based on c₀c₁c₂c₃=“0001” and b₀b₁b₂b₃=“0000”. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

<<Receive Apparatus Corresponding to Example 3>>

-   -   When a transmit apparatus (transmit station) transmits a         modulated signal by “scheme A”:

When the control information estimator A216 of a receive apparatus obtains d₀=“0”, the control information estimator A216 determines that a data symbol is a symbol transmitted by “scheme A”. By obtaining a value of b₀b₁b₂b₃, when the data symbol is a (12,4)16APSK symbol, the control information estimator A216 estimates a (12,4)16APSK ring ratio. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

-   -   When a transmit apparatus (transmit station) transmits a         modulated signal by “scheme B”:

As illustrated in FIG. 55, the control information estimator A216 of the receive apparatus estimates “scheme B” from d₀=“1”, and (12,4)16APSK ring ratio 2.00 from x₀x₁x₂x₃x₄x₅=“000000”. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

<<Receive Apparatus Corresponding to Example 4>>

-   -   When a transmit apparatus (transmit station) transmits a         modulated signal by “scheme A”:

When the control information estimator A216 of a receive apparatus obtains d₀=“0”, the control information estimator A216 determines that a data symbol is a symbol transmitted by “scheme A”. By obtaining a value of b₀b₁b₂b₃, when the data symbol is a (12,4)16APSK symbol, the control information estimator A216 estimates a (12,4)16APSK ring ratio. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

-   -   When a transmit apparatus (transmit station) transmits a         modulated signal by “scheme B”:

As illustrated in FIG. 56, the control information estimator A216 of thereceive apparatus determines that a data symbol is a symbol of “scheme B” from d₀=“1”. Further, the control information estimator A216 of the receive apparatus estimates a difference of +0.4 from y₀y₁y₂y₃y₄y₅=“011110”. Further, based on b₀b₁b₂b₃=“0000”, the control information estimator A216 estimates (12,4)16APSK ring ratio 3.09 prior to taking into account difference, and estimates a coding rate of error correction code 41/120. By summing both so that 3.09+0.4=3.49, the control information estimator A216 estimates a (12,4)16APSK ring ratio 3.49. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

<<Receive Apparatus Corresponding to Example 5>>

-   -   When a transmit apparatus (transmit station) transmits a         modulated signal by “scheme A”:

When the control information estimator A216 of a receive apparatus obtains d₀=“0”, the control information estimator A216 determines that a data symbol is a symbol transmitted by “scheme A”. By obtaining a value of b₀b₁b₂b₃, when the data symbol is a (12,4)16APSK symbol, the control information estimator A216 estimates a (12,4)16APSK ring ratio. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

-   -   When a transmit apparatus (transmit station) transmits a         modulated signal by “scheme B”:

As illustrated in FIG. 57, the control information estimator A216 of the receive apparatus determines that a data symbol is a symbol of “scheme B” from d₀=“1”. Further, the control information estimator A216 of the receive apparatus estimates a difference of ×0.9 from y₀y₁y₂y₃y₄y₅=“100001”. Further, based on b₀b₁b₂b₃=“0000”, the control information estimator A216 estimates (12,4)16APSK ring ratio 3.09 prior to taking into account difference, and estimates a coding rate of error correction code 41/120. By multiplying both so that 3.09×0.9=2.78, the control information estimator A216 estimates a (12,4)16APSK ring ratio 2.78. The de-mapper A206 performs demodulation of the data symbol based on the above estimated information.

(Embodiment D)

In the present embodiment, a method of transmitting pilot symbols based on embodiment C is described.

Note that ring ratio (for example, (12,4)16APSK ring ratio) has been defined prior to the present embodiment, and ring ratio may also be referred to as “radius ratio”.

<Example of Pilot Symbols>

In the present embodiment, an example is described of pilot symbol configuration in the transmit scheme described in embodiment C (a data symbol modulation scheme is (12,4)16APSK).

Note that the transmit apparatus in the present embodiment is identical to the transmit apparatus described in embodiment 1 and therefore description thereof is omitted here.

Interference occurs between code (between symbols) of a modulated signal, because of non-linearity of the power amplifier of the transmit apparatus. High data reception quality can be achieved by a receive apparatus by decreasing this intersymbol interference.

In the present example of pilot symbol configuration, in order to reduce intersymbol interference at a receive apparatus, a transmit apparatus transmits pilot symbols by using a modulation scheme and ring ratio used in a data symbol.

Accordingly, when a transmit apparatus (transmit station) determines a modulation scheme and ring ratio of a data symbol by any of the methods of <Example 1> to <Example 5> of embodiment C, the transmit apparatus generates and transmits pilot symbols by using the same modulation scheme and ring ratio as the data symbol.

The following illustrates specific examples. However, description continues assuming that (12,4)16APSK is selected as a modulation scheme.

In the case of <Example 1> of embodiment C:

When a transmit apparatus (transmit station) transmits a data symbol so that “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 4.00”, d₀=“1”, b₀b₁b₂b₃=“0000”, and c₀c₁c₂c₃=“0001”. Thus, based on “d₀=“1”, b₀b₁b₂b₃=“0000”, and c₀c₁c₂c₃=“0001””, the transmit apparatus sets a modulation scheme and ring ratio of pilot symbols to (12,4)16APSK and ring ratio 4.00 (of (12,4)16APSK), respectively.

Accordingly, the transmit apparatus (transmit station) transmits the following, in order, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio 4.00; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio 4.00.

Thus, a receive apparatus can estimate intersymbol interference with high precision, and can therefore achieve high data reception quality.

Pilot symbols need not be symbols only for estimating intersymbol interference, and a receive apparatus may estimate a radio wave propagation environment between a transmit apparatus and the receive apparatus (channel estimation), and may estimate frequency offset and perform time synchronization using the pilot symbols.

When a transmit apparatus sets separate values for data symbol ring ratios, pilot symbols are changed to the same ring ratio as data symbols (a value L) and the transmit apparatus (transmit station) transmits the following, in order, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio L; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio L.

In the case of <Example 2> of embodiment C:

When a transmit apparatus (transmit station) transmits a data symbol so that “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 4.00”, the transmit apparatus transmits d₀=“1”, z₀=1, b₀b₁b₂b₃=“0000”, and c₀c₁c₂c₃=“0001” control information (a portion of TMCC information) along with the data symbol. Thus, based on “d₀=“1”, z₀=1, b₀b₁b₂b₃=“0000”, and c₀c₁c₂c₃=“0001””, the transmit apparatus sets a modulation scheme and ring ratio of pilot symbols to (12,4)16APSK and ring ratio 4.00 (of (12,4)16APSK), respectively.

Accordingly, the transmit apparatus (transmit station) transmits the following, in order, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio 4.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio 4.00; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio 4.00.

Thus, a receive apparatus can estimate intersymbol interference with high precision, and can therefore achieve high data reception quality.

Pilot symbols need not be symbols only for estimating intersymbol interference, and a receive apparatus may estimate a radio wave propagation environment between a transmit apparatus and the receive apparatus (channel estimation), and may estimate frequency offset and perform time synchronization using the pilot symbols.

When a transmit apparatus sets separate values for data symbol ring ratios, pilot symbols are changed to the same ring ratio as data symbols (a value L) and the transmit apparatus (transmit station) transmits the following, in order, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio L; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio L.

In the case of <Example 3> of embodiment C:

When a transmit apparatus (transmit station) transmits a data symbol so that “satellite broadcasting scheme: “scheme B” and (12,4)16APSK ring ratio: 2.00”, the transmit apparatus transmits d₀=“1” and x₀x₁x₂x₃x₄x₅=“000000” control information (a portion of TMCC information) along with the data symbol. Thus, based on “d₀=“1”, and x₀x₁x₂x₃x₄x₅=“000000””, the transmit apparatus sets a modulation scheme and ring ratio of pilot symbols to (12,4)16APSK and ring ratio 2.00 (of (12,4)16APSK), respectively.

Accordingly, the transmit apparatus (transmit station) transmits the following, in order, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio 2.00;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio 2.00; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio 2.00.

Thus, a receive apparatus can estimate intersymbol interference with high precision, and can therefore achieve high data reception quality.

Pilot symbols need not be symbols only for estimating intersymbol interference, and a receive apparatus may estimate a radio wave propagation environment between a transmit apparatus and the receive apparatus (channel estimation), and may estimate frequency offset and perform time synchronization using the pilot symbols.

When a transmit apparatus sets separate values for data symbol ring ratios, pilot symbols are changed to the same ring ratio as data symbols (a value L) and the transmit apparatus (transmit station) transmits the following, in order, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio L; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio L.

In the case of <Example 4> of embodiment C:

When a transmit apparatus (transmit station) transmits a data symbol so that “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 3.49”, the transmit apparatus transmits d₀=“1”, b₀b₁b₂b₃=“0000”, and y₀y₁y₂y₃y₄y₅=“011110” control information (portion of TMCC information) along with the data symbol. Thus, based on “d₀=“1”, b₀b₁b₂b₃=“0000”, and y₀y₁y₂y₃y₄y₅=“011110””, the transmit apparatus sets a modulation scheme and ring ratio of pilot symbols to (12,4)16APSK and ring ratio 3.49 (of (12,4)16APSK), respectively.

Accordingly, the transmit apparatus (transmit station) transmits the following, in order, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio 3.49;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio 3.49; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio 3.49.

Thus, a receive apparatus can estimate intersymbol interference with high precision, and can therefore achieve high data reception quality.

Pilot symbols need not be symbols only for estimating intersymbol interference, and a receive apparatus may estimate a radio wave propagation environment between a transmit apparatus and the receive apparatus (channel estimation), and may estimate frequency offset and perform time synchronization using the pilot symbols.

When a transmit apparatus sets separate values for data symbol ring ratios, pilot symbols are changed to the same ring ratio as data symbols (a value L) and the transmit apparatus (transmit station) transmits the following, in order, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio L; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio L.

In the case of <Example 5> of embodiment C:

When a transmit apparatus (transmit station) transmits a data symbol so that “satellite broadcasting scheme: “scheme B”, coding rate: 41/120, and (12,4)16APSK ring ratio: 2.78”, the transmit apparatus transmits d₀=“1”, b₀b₁b₂b₃=“0000”, and y₀y₁y₂y₃y₄y₅=“100001” control information (portion of TMCC information) along with the data symbol. Thus, based on “d₀=“1”, b₀b₁b₂b₃=“0000”, and y₀y₁y₂y₃y₄y₅=“100001””, the transmit apparatus sets a modulation scheme and ring ratio of pilot symbols to (12,4)16APSK and ring ratio 2.78 (of (12,4)16APSK), respectively.

Accordingly, the transmit apparatus (transmit station) transmits the following, in order, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio 2.78;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio 2.78; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio 2.78.

Thus, a receive apparatus can estimate intersymbol interference with high precision, and can therefore achieve high data reception quality.

Pilot symbols need not be symbols only for estimating intersymbol interference, and a receive apparatus may estimate a radio wave propagation environment between a transmit apparatus and the receive apparatus (channel estimation), and may estimate frequency offset and perform time synchronization using the pilot symbols.

When a transmit apparatus sets separate values for data symbol ring ratios, pilot symbols are changed to the same ring ratio as data symbols (a value L) and the transmit apparatus (transmit station) transmits the following, in order, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio L; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio L.

Operation of a receive apparatus is described with reference to FIG. 2.

In FIG. 2, 210 indicates a configuration of a receive apparatus. The de-mapper 214 of FIG. 2 performs de-mapping with respect to mapping of a modulation scheme used by the transmit apparatus, for example obtaining and outputting a log-likelihood ratio for each bit. At this time, although not illustrated in FIG. 2, estimation of intersymbol interference, estimation of a radio wave propagation environment (channel estimation) between the transmit apparatus and the receive apparatus, time synchronization with the transmit apparatus, and frequency offset estimation may be performed in order to precisely perform de-mapping.

Although not illustrated in FIG. 2, the receive apparatus includes an intersymbol interference estimator, a channel estimator, a time synchronizer, and a frequency offset estimator. These estimators extract from receive signals a portion of pilot symbols, for example, and respectively perform intersymbol interference estimation, estimation of a radio wave propagation environment (channel estimation) between the transmit apparatus and the receive apparatus, time synchronization between the transmit apparatus and the receive apparatus, and frequency offset estimation between the transmit apparatus and the receive apparatus. Subsequently, the de-mapper 214 of FIG. 2 inputs these estimation signals and, by performing de-mapping based on these estimation signals, performs, for example, calculation of log-likelihood ratios.

Modulation scheme and ring ratio information used in generating a data symbol is, as described in embodiment C, transmitted by using control information such as TMCC control information. Thus, because a modulation scheme and ring ratio used in generating pilot symbols is the same as the modulation scheme and ring ratio used in generating data symbols, a receive apparatus estimates, by a control information estimator, the modulation scheme and ring ratio from control information, and, by inputting this information to the de-mapper 214, estimation of distortion of propagation path, etc., is performed from the pilot symbols and de-mapping of the data symbol is performed.

Further, a transmission method of pilot symbols is not limited to the above. For example, a transmit apparatus (transmit station) may transmit, as pilot symbols:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio L, a plurality of times;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio L, a plurality of times; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio L, a plurality of times.

When the following symbols are each transmitted an equal number of times, there is an advantage that a receive apparatus can perform precise estimation of distortion of a propagation path:

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0110] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[0111] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1000] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1001] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1010] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1011] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1100] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1101] of (12,4)16APSK ring ratio L;

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1110] of (12,4)16APSK ring ratio L; and

a symbol of a constellation point (baseband signal) corresponding to [b₃b₂b₁b₀]=[1111] of (12,4)16APSK ring ratio L.

Frame configurations applicable to the present invention are not limited to the above description. When a plurality of data symbols exist, a symbol for transmitting information related to a modulation scheme used in generating the plurality of data symbols, and a symbol for transmitting information related to an error correction scheme (for example, error correction code used, code length of error correction code, coding rate of error correction code, etc.) exist, any arrangement in a frame may be used with respect to the plurality of data symbols, the symbol for transmitting information related to a modulation scheme, and the symbol for transmitting information related to an error correction scheme. Further, symbols other than these symbols, for example a symbol for preamble and synchronization, pilot symbols, a reference symbol, etc., may exist in a frame.

(Supplement)

As a matter of course, a plurality of embodiments described herein may be implemented in combination.

Herein, “∀” represents a universal quantifier and “∃” represents an existential quantifier.

Herein, in the case of a complex plane, the unit of phase of the argument, for example, is “radians”.

When a complex plane is used, it can be displayed in polar form as polar coordinates of complex numbers. When points (a and b) on a complex plane are made to correspond to a complex number z=a+jb (a and b are real numbers, j is an imaginary unit), when expressing a and b as polar coordinates (r, θ), a=r×cos θ and b=r×sin θ, the following holds true:

[Math 27] r=√{square root over (a ² +b ²)}  (Math 27)

Here, r is the absolute value of z (r=|z|), and θ is the argument of z. Thus, z=a+jb is expressed as r×e^(jθ).

Note that, for example, a program executing the above communication method may be stored on read only memory (ROM) and the program may be executed by a central processing unit (CPU).

Further, a program executing the above communication method may be stored on a computer-readable non-transitory storage medium, the program stored in the storage medium may be written to random access memory (RAM) of a computer, and the computer may be made to operate according to the program.

Further, each configuration such as each embodiment may be implemented typically as a large scale integration (LSI), which is an integrated circuit. This may be an individual chip, and an entire configuration or part of the configuration of an embodiment may be included in one chip. Here, “LSI” is referred to, but according to the degree of integration this may be called an integrated circuit (IC), system LSI, super LSI, or ultra LSI. Further, methods of integration are not limited to LSI, and may be implemented by a dedicated circuit or general-purpose processor. After LSI manufacture, a field programmable gate array (FPGA) or reconfigurable processor that allows reconfiguring of connections and settings of circuit cells within the LSI may be used.

Further, if integrated circuit technology to replace LSI is achieved through advancement in semiconductor technology or other derivative technology, such technology may of course be used to perform integration of function blocks. Application of biotechnology, etc., is also a possibility.

The following provides supplemental description of transmission schemes.

In the description of the present invention, FIG. 29 is a diagram in which a section performing mapping of, for example, the mapper 708 and the modulator 710 of FIG. 7 and a section performing bandlimiting are extracted when single carrier transmission is used as a transmission scheme.

In FIG. 29, a mapper 2902 receives a control signal and a digital signal as input, performs mapping based on information related to a modulation scheme (or transmission method) included in the control signal, and outputs an in-phase component of a post-mapping baseband signal and a quadrature component of a post-mapping baseband signal.

A bandlimiting filter 2904 a receives the in-phase component of the post-mapping baseband signal and the control signal as input, sets a roll-off rate included in the control signal, performs bandlimiting, and outputs an in-phase component of a post-bandlimiting baseband signal.

In the same way, a bandlimiting filter 2904 b receives the quadrature component of the post-mapping baseband signal and the control signal as input, sets a roll-off rate included in the control signal, performs bandlimiting, and outputs a quadrature component of a post-bandlimiting baseband signal.

Frequency properties of a bandlimiting filter performing bandlimiting of a carrier are as in Math (28), below.

$\begin{matrix} {\mspace{79mu}\left\lbrack {{Math}\mspace{14mu} 28} \right\rbrack} & \; \\ \left\{ \begin{matrix} 1 & {{F} \leq {F_{n} \times \left( {1 - \alpha} \right)}} \\ \sqrt{\frac{1}{2} + {\frac{1}{2}\sin{\frac{\pi}{2\; F_{n}}\left\lbrack \frac{F_{n} - {F}}{\alpha} \right\rbrack}}} & {{F_{n} \times \left( {1 - \alpha} \right)} \leq {F} \leq {F_{n} \times \left( {1 + \alpha} \right)}} \\ 0 & {{F} \geq {F_{n} \times \left( {1 + \alpha} \right)}} \end{matrix} \right. & \left( {{Math}\mspace{14mu} 28} \right) \end{matrix}$

In the above formula, F is center frequency of a carrier, F_(n) is a Nyquist frequency, and a is a roll-off rate.

Here, in a case in which it is possible that the control signal can change roll-off rate when transmitting a data symbol, ring ratio may also be changed for each modulation scheme/transmission method along with changes in roll-off rate. In this case, it is necessary to transmit information related to changes in ring ratio such as in the examples above. Thus, a receive apparatus can demodulate and decode based on this information.

Alternatively, in a case in which it is possible that the roll-off rate can be changed when transmitting a data symbol, a transmit apparatus transmits information related to roll-off rate changes as a control information symbol. The control information symbol may be generated by a roll-off rate of a given setting.

(Supplement 2)

Embodiment 12 describes the following.

<Signaling>

In the present embodiment, examples are described of various information signaled as TMCC information in order to facilitate reception at the receive apparatus of a transmit signal used in the transmission scheme described in embodiment 10.

Note that the transmit apparatus in the present embodiment is identical to the transmit apparatus described in embodiment 1 and therefore description thereof is omitted here. However, (4,8,4)16APSK is used instead of (8,8)16APSK.

FIG. 18 illustrates a schematic of a transmit signal frame of advanced wide band digital satellite broadcasting. However, this is not intended to be an accurate diagram of a frame of advanced wide band digital satellite broadcasting. Note that details are described in embodiment 3, and therefore description is omitted here.

Table 18 illustrates a configuration of modulation scheme information. In table 18, for example, when four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0001], a modulation scheme for generating symbols of “slots composed of a symbol group” is π/2 shift binary phase shift keying (BPSK).

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0010], a modulation scheme for generating symbols of “slots composed of a symbol group” is quadrature phase shift keying (QPSK).

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0011], a modulation scheme for generating symbols of “slots composed of a symbol group” is 8 phase shift keying (8PSK).

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0100], a modulation scheme for generating symbols of “slots composed of a symbol group” is (12,4)16APSK.

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0101], a modulation scheme for generating symbols of “slots composed of a symbol group” is (4,8,4)16APSK.

When four bits to be transmitted by a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0110], a modulation scheme for generating symbols of “slots composed of a symbol group” is 32 amplitude phase shift keying (32APSK).

. . .

TABLE 18 Modulation scheme information Value Assignment 0000 Reserved 0001 π/2 shift BPSK 0010 QPSK 0011 8PSK 0100 (12,4)16APSK 0101 (4,8,4)16APSK 0110 32APSK 0111 . . . . . . . . . 1111 No scheme assigned

Table 19 illustrates a relationship between coding rates of error correction code and ring ratios when a modulation scheme is (12,4)16APSK. According to R₁ and R₂, used above to represent constellation points of (12,4)16APSK in an I-Q plane, a ring ratio R_((12,4)) of (12,4)16APSK is represented as R_((12,4))=R₂/R₁. In Table 19, for example, when four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0000], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 41/120 (≈1/3), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is 3.09.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0001], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 49/120 (≈2/5), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is 2.97.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0010], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 61/120 (≈1/2), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (12,4)16APSK, a ring ratio R_((12,4)) of (12,4)16APSK is 3.93.

. . .

TABLE 19 Relationship between coding rates of error correction code and ring ratios when modulation scheme is (12,4)16APSK Coding rate (approximate Value value) Ring ratio 0000 41/120 (1/3) 3.09 0001 49/120 (2/5) 2.97 0010 61/120 (1/2) 3.93 . . . . . . . . . 1111 No scheme assigned —

Table 20 indicates a relationship between coding rate of error correction code and radii/phase, when a modulation scheme is (4,8,4)16APSK.

In Table 20, for example, when four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0000], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 41/120 (≈1/3), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (4,8,4)16APSK, a radius R₁ is 1.00, a radius R₂ is 2.00, a radius R₃ is 2.20, and a phase λ is π/12 radians.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0001], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 49/120 (≈2/5), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (4,8,4)16APSK, a radius R₁ is 1.00, a radius R₂ is 2.10, a radius R₃ is 2.20, and a phase λ is π/12 radians.

When four bits to be transmitted by a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” are [0010], a coding rate of error correction code for generating symbols of “slots composed of a data symbol group” is 61/120 (≈1/2), and this means that when a symbol for transmitting a modulation scheme of a transmission mode is indicated to be (4,8,4)16APSK, a radius R₁ is 1.00, a radius R₂ is 2.20, a radius R₃ is 2.30, and a phase λ is π/10 radians.

. . .

TABLE 20 Relationship between radii/phases of error correction code and ring ratios when modulation scheme is (4,8,4)16APSK Coding rate Value (approximate value) Radii and phase 0000 41/120 (1/3) R₁ = 1.00 R₂ = 2.00 R₃ = 2.20 λ = π/12 0001 49/120 (2/5) R₁ = 1.00 R₂ = 2.10 R₃ = 2.20 λ = π/12 0010 61/120 (1/2) R₁ = 1.00 R₂ = 2.20 R₃ = 2.30 λ = π/10 . . . . . . . . . 1111 No scheme assigned —

<Receive Apparatus>

The following describes operation of a receive apparatus that receives a radio signal transmitted by the transmit apparatus 700, with reference to the diagram of a receive apparatus in FIG. 19.

The receive apparatus 1900 of FIG. 19 receives a radio signal transmitted by the transmit apparatus 700 via the antenna 1901. The RF receiver 1902 performs processing such as frequency conversion and quadrature demodulation on a received radio signal, and outputs a baseband signal.

The demodulator 1904 performs processing such as root roll-off filter processing, and outputs a post-filter baseband signal.

The synchronization and channel estimator 1914 receives a post-filter baseband signal as input, performs time synchronization, frequency synchronization, and channel estimation, using, for example, a “synchronization symbol group” and “pilot symbol group” transmitted by the transmit apparatus, and outputs an estimated signal.

The control information estimator 1916 receives a post-filter baseband signal as input, extracts symbols including control information such as a “TMCC information symbol group”, performs demodulation and decoding, and outputs a control signal.

Of importance in the present embodiment is that a receive apparatus demodulates and decodes a symbol transmitting “transmission mode modulation scheme” information and a symbol transmitting “transmission mode coding rate” of “transmission mode/slot information” of a “TMCC information symbol group”; and, based on Table 18, Table 19, and Table 20, the control information estimator 1916 generates modulation scheme information and error correction code scheme (for example, coding rate of an error correction code) information used by “slots composed of a data symbol group”, and generates ring ratio and radii/phase information when a modulation scheme used by “slots composed of a data symbol group” is (12,4)16APSK, (4,8,4)16APSK, or 32APSK, and outputs the information as a portion of a control signal.

The de-mapper 1906 receives a post-filter baseband signal, control signal, and estimated signal as input, determines a modulation scheme (or transmission method) used by “slots composed of a data symbol group” based on the control signal (in this case, when there is a ring ratio and radii/phase, determination with respect to the ring ratio and radii/phase is also performed), calculates, based on this determination, a log-likelihood ratio (LLR) for each bit included in a data symbol from the post-filter baseband signal and estimated signal, and outputs the log-likelihood ratios. (However, instead of a soft decision value such as an LLR a hard decision value may be outputted, and a soft decision value may be outputted instead of an LLR.)

The de-interleaver 1908 receives log-likelihood ratios as input, accumulates input, performs de-interleaving (permutes data) corresponding to interleaving used by the transmit apparatus, and outputs a post-de-interleaving log-likelihood ratio.

The error correction decoder 1912 receives post-de-interleaving log-likelihood ratios and a control signal as input, determines error correction code used (code length, coding rate, etc.), performs error correction decoding based on this determination, and obtains estimated information bits. When the error correction code being used is an LDPC code, belief propagation (BP) decoding methods such as sum-product decoding, shuffled belief propagation (BP) decoding, and layered BP decoding may be used as a decoding method.

The above describes operation when iterative detection is not performed. The following is supplemental description of operation when iterative detection is performed. Note that a receive apparatus need not implement iterative detection, and a receive apparatus may be a receive apparatus that performs initial detection and error detection decoding without being provided with elements related to iterative detection that are described below.

When iterative detection is performed, the error correction decoder 1912 outputs a log-likelihood ratio for each post-decoding bit. (Note that when only initial detection is performed, output of a log-likelihood ratio for each post decoding bit is not necessary.)

The interleaver 1910 interleaves log-likelihood ratios for post-decoding bits (performs permutation), and outputs a post-interleaving log-likelihood ratio.

The de-mapper 1906 performs iterative detection by using post-interleaving log-likelihood ratios, a post-filter baseband signal, and an estimated signal, and outputs log-likelihood ratios for post-iterative detection bits.

Subsequently, interleaving and error correction code operations are performed. Thus, these operations are iteratively performed. In this way, finally the possibility of achieving a preferable decoding result is increased.

In the above description, a feature thereof is that by a reception apparatus obtaining a symbol for transmitting a modulation scheme of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group” and a symbol for transmitting a coding rate of a transmission mode of “transmission mode/slot information” of a “TMCC information symbol group”, a modulation scheme, coding rate of error detection coding, and, when a modulation scheme is 16APSK, 32APSK, ring ratios and radii/phases are estimated and demodulation and decoding operations become possible.

The above describes frame configuration of FIG. 18, but frame configurations applicable to the present invention are not limited to the above description. When a plurality of data symbols exist, a symbol for transmitting information related to a modulation scheme used in generating the plurality of data symbols, and a symbol for transmitting information related to an error correction scheme (for example, error correction code used, code length of error correction code, coding rate of error correction code, etc.) exist, any arrangement in a frame may be used with respect to the plurality of data symbols, the symbol for transmitting information related to a modulation scheme, and the symbol for transmitting information related to an error correction scheme. Further, symbols other than these symbols, for example a symbol for preamble and synchronization, pilot symbols, a reference symbol, etc., may exist in a frame.

In addition, as a method different to that described above, a symbol transmitting information related to ring ratios and radii/phases may exist, and the transmit apparatus may transmit the symbol. An example of a symbol transmitting information related to ring ratios and radii/phases is illustrated below.

TABLE 21 Examples of symbol transmitting information related to ring ratios and radii/phases Value Assignment 00000 (12,4)16APSK ring ratio 4.00 00001 (12,4)16APSK ring ratio 4.10 00010 (12,4)16APSK ring ratio 4.20 00011 (12,4)16APSK ring ratio 4.30 00100 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.00, R₃ = 2.20, λ = π/12 00101 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.10, R₃ = 2.20, λ = π/12 00110 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.20, R₃ = 2.30, λ = π/10 00111 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.20, R₃ = 2.30, λ = π/12 . . . . . . 11111 . . .

In Table 21, when [00000] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00”.

Further, the following is true.

When [00001] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10”.

When [00010] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.20”.

When [00011] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.30”.

When [00100] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.00, R₃=2.20, λ=π/12”.

When [00101] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.10, R₃=2.20, λ=π/12”.

When [00110] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.20, R₃=2.30, λ=π/10”.

When [00111] is transmitted by a symbol transmitting information related to ring ratio and radii/phase, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.20, R₃=2.30, λ=π/12”.

Thus, by obtaining a symbol transmitting information related to ring ratio and radii/phases, a receive apparatus can estimate a ring ratio and radii/phases used by a data symbol, and therefore demodulation and decoding of the data symbol becomes possible.

Further, ring ratio and radii/phases information may be included in a symbol for transmitting a modulation scheme. An example is illustrated below.

TABLE 22 Modulation scheme information Value Assignment 00000 (12,4)16APSK ring ratio 4.00 00001 (12,4)16APSK ring ratio 4.10 00010 (12,4)16APSK ring ratio 4.20 00011 (12,4)16APSK ring ratio 4.30 00100 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.00, R₃ = 2.20, λ = π/12 00101 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.10, R₃ = 2.20, λ = π/12 00110 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.20, R₃ = 2.30, λ = π/10 00111 (4,8,4)16APSK R₁ = 1.00, R₂ = 2.20, R₃ = 2.30, λ = π/12 . . . . . . 11101 8PSK 11110 QPSK 11111 π/2 shift BPSK

In Table 22, when [00000] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.00”.

Further, the following is true.

When [00001] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.10”.

When [00010] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.20”.

When [00011] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(12,4)16APSK ring ratio 4.30”.

When [00100] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.00, R₃=2.20, λ=π/12”.

When [00101] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.10, R₃=2.20, λ=π/12”.

When [00110] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.20, R₃=2.30, λ=π/10”.

When [00111] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “(4,8,4)16APSK R₁=1.00, R₂=2.20, R₃=2.30, λ=π/12”.

When [11101] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “8PSK”.

When [11110] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “QPSK”.

When [11111] is transmitted by a symbol transmitting modulation scheme information, a data symbol is a symbol of “π/2 shift BPSK”.

Thus, by obtaining a symbol transmitting modulation scheme information, a receive apparatus can estimate a modulation scheme, ring ratio, radii, and phases used by a data symbol, and therefore demodulation and decoding of the data symbol becomes possible.

Note that in the above description, examples are described including “(12,4)16APSK” and “(4,8,4)16APSK” as selectable modulation schemes (transmission methods), but modulation schemes (transmission methods) are not limited to these examples. In other words, other modulation schemes may be selectable.

In embodiment 12, transmission of control information is described in a case in which two different mapping patterns, “(12,4)16APSK” and “(4,8,4)16APSK”, are selectable as 16APSK schemes transmitting four bits of data in one symbol. This may be re-stated as:

“A method comprising: generating a data symbol by using a modulation scheme selected from a plurality of modulation schemes including a first modulation scheme and a second modulation scheme; and transmitting the generated data symbol and control information indicating the selected modulation scheme, wherein:

(i) mapping of the first modulation scheme and mapping of the second modulation scheme each have the same number of constellation points as each other, the number of constellation points being selected according to transmit data, and

(ii) the number of constellation points in a series is different between the mapping of the first modulation scheme and the mapping of the second modulation scheme, the series being the number of constellation points arranged on a plurality of concentric circles having the origin of an in-phase (I)-quadrature-phase (Q) plane as the center thereof, from a circle having the largest radius (amplitude component) to a circle having the smallest radius.”

Here, the number of constellation points selected according to transmit data is, for example, 16 in the case of “(12,4)16APSK” and 16 in the case of “(4,8,4)16APSK”. In other words, the number of constellation points selected according to transmit data is 16 for both “(12,4)16APSK” and “(4,8,4)16APSK”, and they satisfy condition (i).

Further, the number of constellation points arranged on a plurality of concentric circles having the origin of an in-phase (I)-quadrature-phase (Q) plane as the center thereof, from a circle having the largest radius (amplitude component) to a circle having the smallest radius is, for example, (12,4) in the case of “(12,4)16APSK”, and (4,8,4) in the case of “(4,8,4)16APSK”. Thus, the number of constellation points arranged on concentric circles having the origin of an in-phase (I)-quadrature-phase (Q) plane as the center thereof, from a circle having the largest radius (amplitude component) to a circle having the smallest radius is different between “(12,4)16APSK” and “(4,8,4)16APSK”, satisfying condition (ii).

In embodiment 12, transmission of control information in a case in which two different mapping patterns, “(12,4)16APSK” and “(4,8,4)16APSK”, are selectable as 16APSK schemes transmitting four bits of data in one symbol may further be re-stated as:

“A method comprising: generating a data symbol by using a modulation scheme selected from a plurality of modulation schemes including a first modulation scheme and a second modulation scheme; and transmitting the generated data symbol and control information indicating the selected modulation scheme, wherein:

(i) mapping of the first modulation scheme and mapping of the second modulation scheme each have the same number of constellation points as each other, the number of constellation points being selected according to transmit data,

(ii) the number of constellation points in a series is different between the mapping of the first modulation scheme and the mapping of the second modulation scheme, the series being the number of constellation points arranged on a plurality of concentric circles having the origin of an in-phase (I)-quadrature-phase (Q) plane as the center thereof, from a circle having the largest radius (amplitude component) to a circle having the smallest radius, and

ring ratios, which are ratios of radius (or diameter) of the plurality of concentric circles, of the first modulation scheme and the second modulation scheme are selectable, and the control information indicates a selected modulation scheme and ring ratio.”

Note that in embodiment 12, “examples are described including “(12,4)16APSK” and “(4,8,4)16APSK” as selectable modulation schemes (transmission methods), but modulation schemes (transmission methods) are not limited to these examples. In other words, other modulation schemes may be selectable”, is disclosed, and of course “(8,8)16APSK” described in embodiment 1 to embodiment 4 may be selected as one of the “other modulation schemes”.

This is because, in embodiment 10 “embodiment 7 describes a method using NU-16QAM instead of (8,8)16APSK as described in embodiment 1 to embodiment 4, and embodiment 8 describes a method using (4,8,4)16APSK instead of (8,8)16APSK as described in embodiment 1 to embodiment 4” is disclosed, and therefore it is clear that a modulation scheme can use “(8,8)16APSK” instead of “(4,8,4)16APSK”.

Further, for “(8,8)16APSK”, the number of constellation points selected according to transmit data is 16 and the number of constellation points arranged on a plurality of concentric circles having the origin of an in-phase (I)-quadrature-phase (Q) plane as the center thereof, from a circle having the largest radius (amplitude component) to a circle having the smallest radius is (8,8). In other words, selecting modulation schemes from “(8,8)16APSK” and “(12,4)16APSK” also satisfies the above conditions (i) and (ii).

In embodiment 12, when “(8,8)16APSK” is used instead of “(4,8,4)16APSK”, a table is used that replaces the modulation scheme assigned to value 0101 of Table 18 with “(8,8)16APSK”. Further, for instance, Table 3 illustrated in embodiment 2 can be used instead of Table 20. Likewise, a table is used that replaces the ring ratio information assigned to values 00100 to 00111 in Table 21 with ring ratios of “(8,8)16APSK”. Likewise, a table is used that replaces the ring ratio information assigned to values 00100 to 00111 in Table 22 with ring ratios of “(8,8)16APSK”.

Thus, by obtaining a symbol transmitting modulation scheme information, a receive apparatus can estimate a modulation scheme and ring ratio used by a data symbol, and therefore demodulation and decoding of the data symbol becomes possible.

As above, embodiment 12 may be implemented with “(12,4)16APSK” and “(8,8)16APSK” as selectable modulation schemes (transmission methods). Thus, for example, according to linearity (distortion, PAPR, etc.) of a power amplifier used by a transmit apparatus, a more appropriate modulation scheme and ring ratio can be selected, and thereby the likelihood is increased of achieving a reduction in power consumption of the transmit apparatus and an increase in data reception quality of a receive apparatus.

When multicast (broadcast) transmission is used by a satellite, the distance between the satellite and a terminal is far, and therefore when the satellite transmits a modulated signal, the modulated signal is transmitted at high power and use of a power amplifier having high linearity is difficult. In order to ameliorate this problem, high power efficiency can be achieved in a power amplifier of a transmit apparatus by use of APSK that has a lower peak to average power ratio (PAPR) than quadrature amplitude modulation (QAM), and therefore power consumption of the transmit apparatus can be improved. Further, as technology advances, the likelihood of linearity of transmit power amplifiers improving is high. When a power amplifier included in a transmit apparatus mounted on a satellite is exchanged due to maintenance, etc., an increase in linearity of the transmit power amplifier is a possibility. Taking this into consideration, configuring a transmit apparatus so that (12,4)16APSK and (8,8)16APSK ((4,8,4)16APSK) are selectable and ring ratio can be set has the advantage of increasing the likelihood that both a reduction in power consumption of the transmit apparatus and an increase in data reception quality of a receive apparatus can be achieved.

Thus, a receive apparatus of a terminal that receives a modulated signal transmitted from a satellite can estimate data included in the modulated signal by receiving control information transmitted as in the above tables (modulation scheme information, coding rate of error correction code, ring ratio, etc.) and setting demodulation (de-mapping) and decoding (decoding of error correction code).

INDUSTRIAL APPLICABILITY

The transmit apparatus pertaining to the present invention is applicable to communication/broadcast systems having high error correction capability error correction code, and can contribute to improvement in data reception quality when iterative detection is performed at a receive apparatus side.

REFERENCE SIGNS LIST

-   200 transmit apparatus 

The invention claimed is:
 1. A transmit apparatus for transmitting data by modulation schemes that shift amplitude and phase, the transmit apparatus comprising: a selector that selects a first modulation scheme or a second modulation scheme for each symbol in order, alternating between the first modulation scheme and the second modulation scheme, a constellation and bit labelling of each constellation point of the first modulation scheme being different to a constellation and bit labelling of each constellation point of the second modulation scheme; a mapper that performs mapping by using constellation points of a selected modulation scheme; and a transmitter that transmits a modulated signal obtained by the mapping, wherein the number of constellation points of the first modulation scheme is equal to the number of constellation points of the second modulation scheme, the first modulation scheme is a first APSK modulation scheme in which the constellation points are located on the circumferences of two concentric circles that have different radii to each other on an IQ plane, the second modulation scheme is a second APSK modulation scheme in which the constellation points are located on the circumferences of two concentric circles that have different radii to each other on an IQ plane, and a ratio of the first modulation scheme of the number of constellation points on the circumference of the inner circle to the number of constellation points on the circumference of the outer circle is different from a ratio of the second modulation scheme of the number of constellation points on the circumference of the inner circle to the number of constellation point on the circumference of the outer circle. 